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'c'ducation and Architecture in the 20th Century: ASchool Design Workshop (ath, Peterborough, Ontario,"arch 25 -2E, 1060).Ontario Dept. of education, Toronto. school Plarninaand Puilding Pesearcl Section.Mar roF'Cr.; Speeches, Notes, and Group Peports prepared byworkshop participants
FT1PS Price m7-$0.70 FC-T?,.(10Architects, Architectural Character, Ruildinanesian, Component Building Systems, ComnuterAssisted Instruction, Cost Fffectiveness,Educational Needs, Master Plans, *SchoolConstruction, *School resign, *School planning,*workshopsCanada
This report contains speeches and notes of workshopparticipants meeting to discuss improvement of the design andconstruction of elementary and secondary school facilities.Participants included educators, architects, engineers, andcontractors. Twenty-two selections cover such topics as planningcoordination for school construction, cost control on school design,the computer as a teaching aid, and construction systems. Thedesirable characteristics of special facilities for physical andhealth education, music education, media centers, and learningmaterial centers are outlined. Related documents are PA 002 877, FA003 0140, and FA 003 OFO. (Pages 25-29 'nay reproduce poorly because ofmarginal legibility.) (MLF)
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20Education and Architecture in
the 20th Century: the fourth
of a new series of School
Design Workshops held at the
Rock Haven Motor Hotel,
Peterborough, Ontario
March 25th - 26th, 1969
The Ninth Regional School
Design Workshop was held in
Peterborough in March, 1969
The attached speeches and
notes are exact copies of
material received from
participants at the
completion of the Workshop
SCHOOL PLANNING AND BUILDING
RESEARCH SECTION
ONTARIO DEPARTMENT OF EDUCATION
INDEX
Page
Page
OPENING WORKSHOP ADDRESS
THE COMPUTER AS A TEACHING AID IN THE SCHOOL PROGRAM
by S.T. Orlowski, Dip.Arch..M.Sc.,MRAIC,ARIBA
1by G. Bonham B.A.Sc.,P.Eng
31 - 34
CURRENT REGIONAL EDUCATION NEEDS
PHYSICAL AND HEALTH EDUCATION FACILITIES IN SCHOOLS
by R.W. Frosts, B.A
2 - 4
by J.M. Metcalf, B.A.,B.P.E.,M.Ed
34 - 43
CURRENT REGIONAL EDUCATION NEEDS AND THE MASTER
PLAN FOR
PHYSICAL EDUCATION FACILITIES
OUR FUTURE by F.H. Hogle, B.A.,B.Paed
4 - 6
by H.H. Roberts, MRAIC
44 - 47
PLANNING COORDINATION FOR SCHOOL CONSTRUCTION
MUSIC FACILITIES IN SCHOOLS
by W.F. Thom, B.A
7 - 8
by J.A. Coles, MusBac
47 - 50
PLANNING COORDINATION FOR SCHOOL CONSTRUCTION
THE ACOUSTICAL ENVIRONMENT IN A SCHOOL - ABSTRACT
by A.J. Connidis, Dip.Arch.,ARIBA,MRAIC
9 - 11
by V.L. Henderson, P.Eng
51
PLANNING COORDINATION FOR SCHOOL CONSTRUCTION
THE MEDIA CENTRE
by L.S. Ginsler, P.Eng.,B.A.Sc
12 - 13
by N.A. Best, B.A.,M.Ed
51 -
2
THE IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN
THE LEARNING MATERIAL CENTRE
by F.W. Woodcock, F.I.A.S.,F.C.I.Q.S
13 - 15
by B. Quan, B.A.Sc.,P.Eng
52 - 54
IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN
CONSTRUCTION SYSTEMS FOR SCHOOL BUILDINGS
by M.A. MacLeod
16 - 17
by J.C. Rankin, B.Arch.,MRAIC
55 -
IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN
CONSTRUCTION SYSTEMS FOR SCHOOLS - "C.L.A.S.P."
by W.E. Barnett, FRAIC
17 - 21
by S.J. Solomon, Dip.Arch.,AtcIBA
59 - 61
HARD AND SOFT SCHOOLS
by R.G. Rist, B.A
21 - 23
HARD - SOFT SCHOOLS - WHY FLEXIBILITY?
by J.K. Crossley, B.A.,M.Ed
23 - 25
THE HARD SOFT SCHOOL
by A. Barton, B.A
25 - 29
THE HARD - SOFT SCHOOL
by W.A. Strong, B.Arch., MRAIC
30 - 31
OPENING ADDRESS by Mr. S.T. Orlowski
I wish to welcome all the participants from the eastern
part of our Province, other parts of Canada and from the
United Kingdom.
Some of you Ladies and Gentlemen participated
in our previous Workshops and some are taking part in
our endeavours for the.first time.
In past years we have held similar conferences that brought
together school trustees, educators, board officials,
engineers, architects and contractors.
Various papers
were presented and discussions were held, opinions expressed
regarding elementary, secondary and post-secondary schools.
Our present Workshop is dedicated to elementary and
secondary school design.
Any school design is a challenge, both for educators and
architects, because we all realise that schools that are
being built today have to outlast the present time and
still function well in the future.
We must always bear
in mind this simple truth, namely that our children are
citizens of this world and of the world to come.
We are on the threshold of a brand new century.
We are
witnessing a tremendous development in the technical
world.
But let us not be blinded by conquers of science
alone.
Although we marvel at computers and interplanetary
exploits, and these I admit are great achievements, we
must not forget that there are parallel achievements in
other fields - the new philosophy is born to govern our
lives and to prepare us for all these new things and ideas.
"The schools must project an educational philosophy that
emphasizes learning, flexibility and continuity, and that
instills in the student's mind an awareness of impending
social and economic change.
It must also encourage the
students to obtain maximum benefit from their educational
experience by exposure to other disciplines and hence to
an understanding of their interrelationship."
It sounds like a big order, but in view of the findings
of the Provincial Committee on Aims and Objectives of
Education in Schools of Ontario - this order can be filled.
'The 220 - page report reflects the new mood in education
in which it is the responsibility of every school authority
to provide a child-centred learning continuum that invites
learning by individual discovery and inquiry."
The world never stood still, but we never had to cope with
so many changes in such a short time.
Let's hope that
we are moving at present towards a better and happier
world and not to destruction of whole humanity.
The new
world belongs to the new generation, but we will be held
responsible for this generation.
We must do our best.
And when we do all we possibly can, let's hope for the best.
And a small request to wind it up - I expect the full
participation of all present and please do not feel
intimidated - express your views freely.
Only this will
give us the assurance of some positive results.
1
CURRENT REGIONAL EDUCATION NEEDS by Mr. R.W. Froats
It is indeed a pleasure for me this morning to welcome to
Region 9 a cross-section of our people who are here with
a united purpose to improve the design and construction of
our school facilities.
In this respect, on your behalf, I would like to take this
opportunity of thanking Mr. Orlowski and the officials of
the Department of Education's School Planning and Building
Research Section for making this Workshop available to
the Region.
The Ontario Institute for Studies in Education has asked
the question:
"Where are ideas to come from in planning
the design of a school and its total environment?"
Changes in educational ideas and procedures, and new
concepts come from a variety of sources; at the important
grassroots of the_system, teaching personnel will repeatedly
perceive problems and lock for answers.
Their contribution
is a remarkable one in the field of action research leading
to acceptable changes regarding facilities to house new
teaching aids and teaching techniques.
Teachers should
always be consulted when new facilities or changes in
facilities are being considered.
!Men, of course, we must recognize that changes come from
without as well as from within.
The alert trustee soon
becomes aware of new developments in educational techniques,
and in order to establish policies regarding financial
arrangements, structural and design possibilities, he looks
for assistance from the professional group of architects,
engineers, and contractors to bring the project through its
various stages to completion.
In summary then, we conceive of a great team, composed of
researchers, educators, architects, engineers, contractors,
all of whom I suspect are represented in this gathering
this morning.
2
The prime interest of each of us in our presence here
this morning and for the next two days is to consider ways
and means of providing the most efficient and practical
facilities to assist in the best education for our boys
and girls of Ontario.
As kick-off speaker therefore, I am now going to take
advantage of my allotted time to summarize for you the
changing approach to learning over the past few years.
From a study of the learning conditions we establish our
building requirements and our overall plans for the region.
The learning situation in to-day's classroom, particularly
at the primary level, provides marked contrasts with that
of yesteryear.
It is much less formal, less rigidly
structured, less tense, less teacher dominated.
Group
teaching and individual learning programs centred around
interests, are used frequently to supplement and replace
instruction of the entire class.
The teacher motivates,
suggests problem areas for investigation, asks some key
questions, arouses an interest, guides, provides resources
for obtaining information, and generally facilitates the
pupils of the group in their inquiry.
The pupils observe,
do, handle, feel, experiment, question, discuss, debate.
They are not quiet, passive, submissive.
They, instead
of the teacher, do most of the asking, talking, responding,
reacting, doing.
The learning is often cast in a game
situation, especially in the primary grades, and there is
laughter and good fun.
When a child begins to play games
with things that stand for other things, he enters the
gateway to reason and imagination.
Learning needs not
be painful nor always serious.
Certainly children in
their learning seem happier, more relaxed, more eager
to inquire and to discover than they were a few years back,
and this is as it should be.
It is evident too that, in
such a climate, they accept more responsibility for their
own learning, and are more self-directing and more
sensitive to life about them, than ever before.
The process of learning is stressed, rather than the
memorization of a catalogued set of facts.
Some facts in math-
ematics, science vocabulary etc. must, of course, be committed
to memory, but need to be learned, not in a vacuum, but in a
total context related to one's needs, to the task in hand,
and to using those facts.
There is increasing recognition
that concepts of the abstracc can be developed only on a
foundation of direct experience with the concrete.
To
this end teachers are providing for interest centres in
their classrooms, for field trips and excursions and for
experimentation.
These spark inquiry and research through
use of library, films, laboratory, and provide the stuff
on which other concepts and language are built.
In certain respects the above remarks perhaps apply more
to the elementary school than to secondary.
However, in
the high school too there is increasing use of group
instruction, of the seminar approach, of learning by dis-
covery, of doing rather than trying merely to soak up,
of much more pupil involvement, of more flexibility in
courses of study.
Also there is growing acceptance that
all students in a grade need not cover the same work in
all subjects, but that a group or even an individual should
be permitted to investigate a topic or unit of work in
which he has particular interest, at great depth, and
omit others completely.
The number of obligatory subjects
is decreasing and the list of optional ones from which
the student may choose in accordance with his interests,
is increasing.
In the elementary panel and also in the
secondary, there is a changing emphasis on examinations.
The tendency is to reduce the number and length of formidable
term examinations, to rely more on short tests and continuous
assessment, and to use tests more as diagnostic instruments
to indicate where more teaching and learning is needed,
rather than as hurdles for failing pupils.
Schools are placing more responsibility for self-direction
and self-determination on all pupils, but particularly at
the more senior levels, and students are in general,
responding positively.
The success of the Senior Plan
in the secondary schools, is clear evidence of this. There
is a growing demand amongst senior students that they be
treated more as partners in the educational enterprise and
that they be given some voice in discipline, curriculum and
in organization.
It would seem that their vast potential
might well be utilized in dealing with some of these matters
and that their opinions would frequently be useful.
The
'Forum' device initiated in many secondary schools, is a
promising approach to this proposition.
Such means as this,
will assist in developing in a student a sense of responsibility- -
a two-fold responsibility, to himself and to society--which
will cause him to use his talents in such a way as best to
serve his fellow-man.
And that is what education in a
democrary is all about!
In the past ten years we have witnessed a most exciting era
in the development of educational methods and procedures
in Ontario.
To meet the changing conditions as outlined
above, we have experimented in Ontario in many new fields
such as:
(a)
The Junior Kindergarten
(b)
Kindergarten proper
(c)
Discovery approach to learning
(d)
The ungraded elementary school
(e)
Subject promotion in the secondary field
(f)
The extensive use of audio-visual aids
and total immersion
(g)
Team teaching
(h)
Individual timetabling
(i)
Seminar teaching
(j)
The development of television
(k)
The provision of psychological servi:es
(1)
Special education for the handicapped
(m)
The outward bound programs - use of
resources of the community
(n)
The provision of teaching-aids & resource centres.
(o)
Special vocational schools
(p)
Comsrnity use of schools
(q)
Summer school for acceleration
I have purposely omitted the use of the computer as an
individual instructional technique for the average school.
It is my belief that it will remain in the experimental
field for at least the next ten years.
Now, ladies and gentlemen, to take stock, we are entering
an era in education when we have the following realities:
(a)
A wealth of tested innovative ideas for the
improvement of instruction in our schools.
(b)
In the new County Board of Education System
of Administration, the means whereby any or
all these ideas are now educationally and
economically feasible.
(c)
According to the winds of rumour from all
levels of government, we are entering what
we hope is only a mild degree of economic
austerity.
3
In the light of these realities and at the risk of being
termed reactionary, I would like to see us enter a period
of "temporary" stability in which we might be given an
opportunity to develop and consolidate our gains of the
past decade.
Change we need, but "change of change" and
change for the sake of change could easily lead us into
chaos.
During the past 20 years we have witnessed a tremendous
period Gr expansion and change in all sectors of our
economy.
Yes, and apparently even to the extent of
expansion beyond the extent of our resources.
We are not
alone in education, we now see all levels of government
obliged to "batten the hatches" and cool the fires of an
over-stimulated race for progress and change.
Let us consolidate our gains and be prepared to advance
When reasonable stability in all sectors of the economy is
established once again.
Finally, how do we summarize our message to those of you
who are responsible for the provision of school facilities.
With the miriad of ideas for improved methodology, it is
certain that we are unable to generalize.
In the final
analysis, our purpose is to build facilities to meet the
needs of the programs offered in the school area.
It is
the responsibility of the educators to determine the best
programs to be offered in the school, for the trustees to
determine policy and provide finance, and for the architects,
engineers and contractors to come up with the plans for
the provision of adequate facilities at a cost which can
be covered by the resources available.
4
CURRENT REGIONAL EDUCATION NEEDS AND THE MASTER PLAN FOR
OUR FUTURE by Mr. F.H. Hogle
Mr. Chairman and ladies and gentlemen; Mr. Froats has
discussed with you the new dimension of educational admin-
istration - the larger unit for school organization and
some of the things we sh.uld look forward to as a result.
His remarks have been aimed at giving perspective and
breadth to this conference.
My role, then, as I see it,
is a bit more myopic:
now that we are aware of the new
and broader vistas opened up by the educational reorganization
to focus upon the educational process as it takes place
in the learning situation.
In ancient times there lived in the north of Greece, King
Midas, who was greedy for gold - so greedy in fact that
he wished that everything he touched should turn to gold.
Dionysus, the god of wine, in return for a favour done,
granted the request.
Midas made use of his power to turn
his furniture and a twig from a tree into gold.
Delighted
with his gift, he kissed his daughter only to find that
she became a golden statue - the gift which he had asked
for had destroyed the one whom he loved most.
Perhaps from this there is a lesson to be learned for those
of us involved in education.
We know that schools exist for children - and must therefore
be child-centred.
If ever we have operated any other type
of system we have been wrong.
Who is this child who we
are to educate, and what is our purpose?
If the Keiller-McKay Report on Religious Education had not
already been published, I suppose I could say that the
writer of Genius has already answered my two questions:
"And God created man to his own image:
to the
image of God he created him:
male and female he
created them".
God made man in his own image...each with a touch of the divine.
"And God blessed them saying:
Increase and
multiply and fill the earth and subdue it".
Now I sometimes think that man has become so absorbed in
the first half of this command - in the increasing and
multiplying - in procreation - that he has neglected the
second half - i.e. "the subduing of the earth".
We should
note that God has given the earth and its resources to man -
and man is to probe the earth, to make it yield us its
secrets, to make it serve him.
Now it would be a cruel thing to give a man a task and
no weapon to accomplish that task.
Man's weapon is his
Intellect - his mind.
We learned a bit about how it works
in our courses in psychology during our teacher training.
It was a theoretical approach - descriptive - telling us
how the child learned.
But I think we should note the new
psychology that is abroad as set forth by Dr. Maltz in his
Psycho-Cybernetics and Dr. Hart in his Autoconditioning.
This new psychology - is not only descriptive but also
Prescriptive - it does not tell us what happens but how
to make it happen.
Dr. Maltz tells of three groups of golf players:
the one
group practised to improve their scores, the second group
did not practise, and the third group practised at home in
their armchairs - they pictured the ball on the tee, the
swinging club, the impact of ball and club, the soaring
ball, and the hole-in-one - all in their armchairs.
It is
to be expected that the group which practised should improve -
and they did by 24%.
It is to be expected that the group
Which did not practise should not improve - and they didn't.
But what of the armchair practisers - the one who engaged
in only imagining?
They improved almost as much as those
who actually practised - 23%.
In short an idea impressed on the mind is a powerful thing.
To put it differently:
what we think we are is more important
than what we actually are...for we become what we think we
are.
The girl who pictures herself as unsuccessful, as
a wall flower, will remain just that.
Teachers must then
become, more active in helping strdents to improve their self-
image - to picture themselves as they should be, to re-picture
themselves as they would like to be...and, if repeated often
enough, that they will become.
Such is the child then:
a being made to the image and
likeness of God with a tremendous capacity for fulfillment
in terms of the images that are fed into his mind.
And the divine command to this child is to subdue the world.
But before one can subdue the world he must know the nature
of that world.
A world full of impact impinges and must be made to impinge
upon the child.
I suppose those of us who are engaged in
education must at times shield the child from his environment
in order to ensure that confusion does not result from a
multiplicity of sensations.
But a child must experience
his world - first hand out of the classroom:
on field trips
to study the flight of the hare before the pursuing fox,
on visits to the maple syrup bush to watch the bubbling
sap, on tours of the countryside to come to appreciate
the resources of his country.
But it is not practical -
nor is it desirable - that he experience everything first-
hand. There is a place for vicarious experiences - to taste
them second hand.
In the classroom, in the lecture hall,
in the auditorium, - through the film, the slide, the
taperecorder, the record, the picture
- to experience
that world as it existed in the past and as it exists now
on one side Daedulus, the carpenter of ancient Cute, who
made wings of feathers for himself and his son Icarus
and fastened them on with wax - on the other three astronauts
spending Cnristmas orbiting the moon; on one side Pericles
consoling the Athenian parents bereaved of sons during the
Peloponnesian war - on the other, a woman who has been
widowed in Vietnam; on the one side the ancient Egyptians
building their tombs with slave labour, hauling 21/2 tons
rock up the side of the pyramid
- on the other the modern
builders, with cranes fitting steel girders into place
high above the city street.
In short I suppose the role of the school is
very simple
- that of setting up a connecting link between the child
and global village in which we live.
In this whole picture
the teacher plays a vital role:
her role is not so much
that of a dispenser of facts
- as it has been in the past.
Rather she makes use of the technology
- the software
and the hardware, if they can do as successful
or even
5
more successful job than she can - a film to teach the
geography of Africa, a record of Maurice Evans in the role
of Shakespeare's "Hamlet", a visit to the museum to see
Eskimo life, a taperecording of the recent visit to the
city council.
And therefore is the teacher obsolete?
Can her place be
taken by a technician who presses buttons, changes film,
splices tape.
No - but her role is altered:
she is not
so much a purveyor of facts, but rather a helper of children
in the analysis, the interpretation, the criticism of
facts:
The recently published Keiller MacKay Report on Religious
Education shows the teacher's role.
The class has studied
Allen Sullivan's story of the Indian half-breed who had
dragged a toboggan laden with food through a blinding
storm.... starving.
The discussion - teacher led - centres
around the moral question of whether the half-breed would
have been justified in eating the food which did not
belong to him.
The facts are put across, somehow, but
it is the teacher who performs the highly skilled task
of leading - or guiding - better perhaps of training
children to guide - the discussion.
Any yet in all that I have talked about - there is - danger.
One can build a self-image that can enhance, endow...as
when one helps a child to appreciate the beauty of a tender
snowflake - or one can build a 'elf image than can destroy,
brainwash.
One can use technology that teaches geography
and history - but can also teach hatred, violence, racial
discrimination and intolerance,
And so
Midas turned his daughter whom he valued most into a cold,
unyielding golden statue.
We who place our faith only in
prescriptive self-image psychology, and cold technology
can do the same with our children - turn them into fact-
carrying robots.
The very technology that can lead to
heaven can also consign to hell.
The teacher, however,
with her warmth of personality, her human qualities can
develop a proper atmosphere for her pupils and bring out
the insight into human problems.
6
And how then does all this -
- the child made to the image of God,
- the divine command to subdue the world,
- the value of the self-image,
- the technology of education,
- the teacher as a skilled professional,
how does all this fit into a conference on school
design?
I recall a Director of Education who was asked his
philosophy of education - it should be noted that he was
coping with a burgeoning school population - smiled and
replied -
"My philosophy is to get them in out of the
rain."
Well, in every pragmatic terms the education process in
our northern climate must at times be brought in out of
the rain - and I may add in out of the snow, the sleet,
the zero weather.
We will be talking about school design at this workshop,
but let's remember that we design schools in which the
central figure is the child in contact with his environment
and reacting thereto.
Schools must never be
- monuments to architects
- memorial to board members
but rather homes where God-given talents may have
an opportunity to develop under the guidance of thoughtful
teachers.
Such is the task - such is the challenge we face today
and tomorrow.
PLANNING COORDINATION FOR SCHOOL CONSTRUCTION by Mr. W.F. Thom
I am pleased to be participating in this conference because
I am so enthusiastic about the opportunities given to the
new county Boards of Education.
They have been challenged
with the task of creating equality of opportunity for their
elementary and secondary school pupils within their several
jurisdictions and jointly across the province.
This lofty
objective should be approached not by strengthening the
weak schools at the expense of the strong but by striving
to improve the best schools and, at the same time,
accelerating needed changes in the others.
This conference, I believe, will confine its deliberations
to one aspect of the challenge--the provision of good
accommodation for the pupils and the steps that each Board
should consider in order to achieve it.
In many counties, the Interim School Organization Committee,
which did such valuable preparatory work for the County Boards,
studied existing accommodation and future needs and devoted
a section of its report to its findings and suggestions.
It is to be expected that this section will be examined and
considered carefully but that the new Boards will wish to
conduct their own studies, keeping in mind the broad aspect
of their responsibility and being mindfal of all advice
available to them.
Such studies may well result in fewer
but larger schools with elimination of municipal boundaries
in favour of natural lines.
To establish future secondary school needs, enrolments in
the feeder elementary schools are available and should be
studied in conjunction with retention patterns developed
in the secondary schools.
Elementary enrolments can be
forecast from numbers in the present grades together with
figures for pre-school children which are available from
municipal clerks or county health units.
Industrial
development may result in an immediate substantial increase
in elementary figures but corresponding increase in the
secondary population will be deferred for several years.
In all cases, additions or new schools should be planned to
meet accommodation needs for five years from the date of
completion substantial building programs for secondary
school purposes require two years to plan and implement.
When the number of new pupil-spaces to be provided has been
established and the location of the addition or
new school
has been determined, details of the type of program to be
offered must be considered.
Visits to new schools in other
counties are strongly recommended for board members,
administrative personnel, teachers, and others who will be
offering advice.
New concepts in school design should be
studied.
In the case of secondary schools, advisory
vocational committees, perhaps with co-opted members, should
be active.
Involvement of interested lay and professional
people is highly desirable.
When the essential features
have been tentatively agreed upon, a Building Proposal should
be submitted to the Regional Business Administrator.
On
acceptance, the Board will be advised of the amount of
departmental grant that can be expected if the building
program is completed.
At this point, many Boards feel that
the advice of an architect is essential, although departmental
policy discourages the selection of an architect at this
juncture.
The Board may estimate the cost of the building
on tne basis of the number of square feet. allow for
furniture, architect's fee and school site, if applicable,
and hence determine the debenture that will be required.
The Municipal Board must then agree to let the Board issue
debentures up to this amount if the project is togo ahead.
Many Boards have been able to finance new construction at
attractive borrowing rates through the Ontario Educational
Capital Aid Program but this source has become inadequate
to satisfy recent demands on it.
An architect may now be engaged with the blessing of the
Department and sketch plans may be developed and presented
to the Department for approval or revision.
Final plans
and specifications will then be prepared and submittedto
the Department and through it to the Provincial FireMarshal's
Office.
When all steps are approved, grants are recalculated,
and tenders may then be called.
if the most attractive bid
is within the amount previously approved by the Municipal
Board, financing arrangements will be verified and, if
satisfactory, a contract may be signed.
The planning stages may be expected to extend
over a twelve-
month period and major construction contracts willrequire
a year to complete.
7
As construction proceeds, the architect should approve every
step in the contract.
Frequency and quality of supervision
are important to the final result and should be negotiated
with the architect when he is engaged.
Channels of communi-
cation between the Board and the contractor should be
through the architect
Education officials on the spot
should convey requests for minor revision of plans to the
Board for action--only the architect authorizes or directs
the contractor to revise plans or specifications.
Progress
payments will be made to the contractor as the architect
authorizes.
A percentage hold-back is intended to ensure
prompt attention to the correction of deficiencies that may
become apparent in the new building.
When all corrections
have been carried out and the time specified for hold-back
has expired, the Board should direct its solicitor to
ascertain if the building is free of liens, and, if so, it
should then pay the balance of the contract.
The responsibility
of a conscientious architect does not end here, he will
continue to investigate and advise when new problems come
to light.
In fact, if a problem presents itself because
of faulty design, the architect and not the Board should bear
the cost of correction.
With the employment of experienced administrative officials
having backgrounds in education, Boards should look first
for features in their building programs that are desirable
from an educational point of view
then they should select
the architect who can best incorporate these features.
Too
often in the past, the architect looked for this advice,
and when he did not receive it, he was forced to rely on
his technical knowledge and experience.
Boards should expect their administrations to be constantly
alert to trends and projected needs.
School sites should
be reserved as subdivisions are planned.
Five-year projections
of capital needs should be as accurate as possible to avoid
future delays in obtaining Municipal Board approval for
building projects.
Grant regulations should be studies in
order to enable Boards to take maximum advantage of their
provisions.
With the cost of amortizing twenty-year debentures more than
double the original debenture, should Boards consider their
potential to build small schools and modest additions from
current funds?
8
To reduce delays in obtaining building project approvals,
could the Department of Education and the Municipal Board
agree in advance on the amount that_ ^ach County Board of
Education would be permitted to debenture in each of the
ensuing five years?
If our educational planning is to show continued progress,
no school will ever be built that will completely satisfy
the aspirations of those who will labour in it.
PLANNING CO-ORDINATION FOR SCHOOL CONSTRUCTION by Mr. A.J. Connidis
Here then is the first task of planning co-ordination, that
of land use.
Let us avoid placing a school on a main highway
if we can, it has happened and children have been hurt
because of it.
The popular magazine description of the architect is often
given as the "creator of buildings" or "the moulder of our
cities" "shaper of our environment" and similar exotic titles.
No doubt several contractors nnd engineers could provide
other names, but really I think the architects' main task
in this fluid society of ours is that of an imaginative
co-ordinator.
I don't think the grandiose titles have ever
been his, or actually claimed by him.
It is the man who successfully exploits a potential source
of weath, or the man with an idea, such as the automobile
or aeroplane, who creates the demands and ensuing need for
labour and accommodation.
This need has to be met and
ultimately may require the servicq of an architect.
Lest I sound too humble, there is quite a special skill
involved in enclosing a space, not least of which is the
ability to visualize something in three dimensions and living
colour before it exists, and then to get the man who is
paying for it together with a whole group of fellow specialists,
to share your vision and help make it work.
Nevertheless
a space use problem must first be presented to the architect
and it is then his direct responsibility to translate it
into a physical form.
Up to the time someone says "We need an eighteen room school
right here and the price must not exceed so many dollars"
several people may have already been involved, often excluding
the architect.
This is an undesirable situation when a
potential source of skill is not used.
If an architect has
been engaged to design a school, or any other type of
building for that matter, he should be called upon to advise
in the preparation of design briefs and to study master plans
in order to select a site.
Too often we are asked to add to a building which was not
designed for it's ultimate capacity on a site which is unsuitable
and may be regularly flooded by the spring run-off.
The school site can form the nucleus of a community, for
example, a school in a centrally located park providing
vistas of trees and open grassy area, with perspectives of
streetscapes which may otherwise be lost.
Such siting may
form the basis for expansion into a community complex when
the school building may offer facilities for community use
or in conjunction with adjacent communal buildings, such as
ice rinks, swimming pools, theatres and even shops.
This
sort of planning will surely lead to a more economical use
of public funds.
From the site to the building.
Given a basic accommodation
requirement, let us talk to one another before we design
anything.
Let us hear the voices of responsible board members,
Directors of Education, Area Superintendents, school principals,
teachers, maintenance men, and also students.
It is often
a conflicting voice, sometimes a tirade, but never one
without enthusiasm.
It is a voice of many different experiences,
and changing requirements which must be heard, and it is
the architects' responsibility to try and make sure that it is.
The architect must analyse the demands, consider the suggestions,
study the criticisms as objectwely as possible, study user
occupation of existing buildings, and establish a rapport
between owner, user and designer.
Then follows a synthesis
into a design for a building which will happily meet all
structural, atmospheric, aesthetic and financial requirements
as interpreted by the architect and his consultants working
as a co-ordinated planning team.
During the planning process we need to look continuously
at our latest ideas already incorporated into existing schools
and see how they are working out, and to see if manufacturers'
Products are living up to their promise
It is very easy
to repeat an attractive new experiment in the name of the
"latent thing".
Ask yourself the following questions:
Are fully carpeted floors the best thing for
kindergartens?
They are nice to sit on, nice to sleep on,
quiet, pretty, reasonable for normal maintenance, but a bit
of a nuisance when children are ill, or twenty of them are
using paint or glue at the same time.
9
How easily can you add two classrooms to a circular
school?
The circle is a pretty complete shape.
Even a
polygonal plan can present some problems in this regard.
How can you demonstrate a tape recorder to a small
group of children in an open classroom with another group
talking behind an adjacent movable storage unit?
Are stairs in again?
In an era of high land costs
it is still easier to make small additions to single storey
buildings.
How successful is team teaching really?
People
are still people and some teachers are not too k,en on
working in front of one another, not all parents like to
instruct their children in front of their neighbours.
It may well be argued that it is as difficult to provide a
standard planning solution to a school as it is to provide
a standard house plan.
The architect must try to assess
all the needs of a particular client relatively, and be able
to sense variations of similar requirements.
From the research to the detailed design, given the require-
ments the architect will formulate ideas and evolve an
initial concept sufficient for early discussion with his
consultants.
TI;te consultants are still nominally three
engineers, structural, mechanical and electrical, together
with perhaps a landscape architect, interior designer and
the developing specialist, the quantity surveyor or cost
control advisor.
Preliminary structural considerations will include the study
of soil and rock conditions, the use of building elements
such as movable partitions which may lead to high point loads.
If, for example, we use movable partitions this means we
will not have any fixed internal walls to use for holding
up upper floors or the roof.
So we will need scam bigger
beams or special structure to span longer distances.
This
will cost more money, is it justifiable?
Will the movable
partitions really be moved by the user?
How easy should
it be to move the partitions?
Should the teacher, the janitor,
or a construction crew be able to move them?
I have heard
of a school where movable partitions have not been moved
since they were installed four years ago.
In some cases the
10
requirement of movable partitions may vanish with the
transfer of a principal.
Movable partitions affect the complexity of mechanical and
electrical layout with regard to heating, ventilating and
plumbing locations, as well as the position of light fixtures,
switches, controls, signal and communication systems, and
audio-visual power points.
Hand in hand with the movable
partition comes the windowless area and its treatment.
Should we have windowless rooms at all?
Is it practical
to cut people off for prolonged periods from visual contact
with the outside world of which they are a part?
It is
certainly cheaper to build external walls without windows.
There is less heat loss in the winter and heat gain in the
summer.
The problem of glare and darkening rooms for films
is eliminated.
However additional factors appear, we must
have improved ventilation, and some form of cooling system
becomes essential.
It may also be noted that an electrical
power failure renders such a building useless at any time
of the entire year, and the number of potential exits in
case of a fire emergency is greatly reduced.
Incidentally, whilst visiting schools in Syracuse, N.Y.,
where windowless classrooms were tried some years ago, I
was told that a very small number of children were adversely
affected by this form of enclosure, so much so that it was
made mandatory that some form of window be provided in
public school classrooms.
Such features as this must be assessed and their relative
merits and costs approximated and a feedback of information
provided to the owner in order to further determine planning
direction.
Higher costs may be acceptable to an owner
convinced of the desirability of a particular feature.
Speed
of construction may be an offsetting feature in considering
higher construction costs.
Time is a most critical planning element and must be
co-ordinated particularly when considering such items
as
the availability of materials, local building
programmes,
current building techniques when the familiar may be dealt
with much faster than the new innovation.
Having dealt with as many requirements as are apparent at
this stage, the architect must present a preliminary plan
and estimate of cost to the School Board.
From this presentation
a Board decision may be obtained and approval to proceed
with final plans and specifications given to the architect.
Final drawing production presents the normal problems of
co-ordination between the architect and his consultants,
decisions on the type of structure and heating system,
down to the type of paper towel holder.
This will include
heating duct sizes co-ordinating with beam sizes to give
adequate clearances without hanging below the ceiling,
ensuring that high level cupboard doors don't hit suspended
light fixtures, laying out systems so that they may be easily
extended and maintained, and selecting equipment that may
be serviced quickly with parts from local sources.
Mention was just made of the critical factor of time.
This
is a problem which may be helped by staggering building
programmes.
Not only would this be of help to architects,
but to contractors as well and in fact to the whole industry.
Most importantly it would help the school building program.
We realise it is not easy to predict enrolments, and
provincial, county and municipal budget dates are fairly
inflexible and subject to many pressures, but something of
this nature will have to be done if we are ever to dispense
with the annual September school sweepstakes.
The concentration
of building programes beginning in Janurary for occupancy
by the following September, inevitably lead to higher prices,
erosion of quality and a strain on suppliers.
This is
regularly manifested on the site in the form of fictitious
delivery dates, leading to delayed completion and a temporary
severe shortage of accommodation.
In addition we develop
irritated teachers, irate parents, persecuted school board
members, hounded architects, and frustrated contractors.
Nevertheless the real loser is still the taxpayer and particularly
the school child who may be disturbed two or three times in
his public school career by crowded and inferior accommodation
and even a hostile environment in the case of pupils of a
temporary "host" school.
Perhaps I hear a murmur "WI/ don't architects get their plans
out faster".
Even if drawing production time was halved it
would not relieve the concentrated requirement.
Perhaps
manufacturers should by now be better prepared for this
pressure which has become the annual norm.
It is invariably
the supply of parts which is given as reason for delay of
the whole.
It is invariab..y the supply of parts which is given as reason
for delay of the whole.
Erection and on site work never
seems to be a problem according to the general contractor,
that is until there are a few strikes to contend with.
It
is most infuriating for the architect to see the job at a
standstill waiting for materials, afterall the effort that
has gone into preparing plans quickly and agitating for
approvals.
With the completion of working drawings, specification and
estimates the architect makes a presentation to the school
board for final approval and assists in their processing
through the provincial Departments.
Once again the speed
of approval is significantly affected by the building program,
for approving authorities are invariably loaded with projects
at the same critical period each year.
After receiving approval the drawings are ready for tender,
the moment of truth is at hand, we will soon know for
exactly how much someone is prepared to build the school
and how long he thinks it will take him.
Great hopes are
embodied in the tender drawings.
They represent the efforts
of a large number of people from many walks of life and
this combined effort is for one purpose, to provide good
and economical schools for our children.
It is the role of the architect to co-ordinate this effort
into a plan and to produce drawings which contain accurate,
clear and complete information to fulfill the intentions of
all those who have participated in the project.
We now move into the area of planning and co-ordinating
the actual building operhtion, which involves another and
most vital member of the team, without whom not much would
be done.
I refer of course to the building contractor.
Close liason and interchange of information must be developed
quickly between the architects' team and the contractor.
The sequence of work must be carefully planned and all
necessary shop drawings swiftly prepared and processed,
if the completion date is to be met.
11
PLANNING COORDINATION FOR SCHOOL CONSTRUCTION by Mr. L.S. Ginsler
One of the most serious problems affecting the planning and
coordination of any project is the difficulty in interpreting
correctly the requirements of the owners, architect and
all the consultants with regard to the required building
services, construction methods and environmental standards.
This becomes increasingly more difficult as the mechanical
and electrical services become more sophisticated each day
and where the architect insists on separating the consultants
from direct contact with the owner's staff in the early
design stages.
Frequently, the only personal contact arises
when operating difficulties occur or omissions become
apparent which require direct confrontation and explanation.
It is indicated that a closer direct working relationship
with the client can establish a rapport and liaison which
can frequently prevent misunderstandings which arise as
the result of information being passed on second and third
hand.
Even where the personnel involved have worked with each
other before and all are familiar with the procedures of
each of the organizations, the many decisions frequently
relayed verbally and through various staff members can
be misunderstood and assumptions based on previous projects
found to be incorrect.
In some school projects and for that matter most Government
projects, a brief is frequently prepared outlining the
program and purporting to clarify the requirements.
Unfortunately, in many instances these tomes contain
information gathered by staff unfamiliar with construction
in general and building services in particular and considerable
care and judgment must be exercised in the interpretation
of the presentations.
In one instance it was indicated
in the brief that a temperature control of 75°Ft 10°was
required and this was understood initially as a requirement
to be able to adjust room conditions by 20°F.
In fact,
12
it turned out instead to be a directive by a scientist
not having a full appreciation of normal environmental
standards.
He was simply indicating what in his mind
was an allowable tolerance from the 75°F norm.
The final
solution was the usual 75°F standard with a tolerance
of ± 111°F.
Many of the universities and lower school boards define
now the minimum construction standards in written form
and these are issued with each project to the design
team.
This can be of very substantial help in the early
concept stages.
Unfortunately, these directives are
often authorized by maintenance staff whose sole interests
lie in reduced operating costs and who have little, if
any, responsibility for initial capital costs.
Without
careful and constant supervision this can result in the
application of standards and the use of products out of
keeping with the rest of the project and the budget and
create "empire" building.
It is suggested, therefore,
a'
a part of the team coordination
that each of the principals involved prepare formats listing
direct questions, assumptions and understandings with respect
to their aspect of the work.
In the mechanical and electrical
field, for instance, I would normally prepare such a
questionnaire in three parts; one dealing with such general
items as glazing (double or single), insulation (material
and thickness),budget, completion dates, etc. and two
other sections dealing with specific mechanical and electrical
questions.
As a matter of convenience I prepare these in
such a form that the answers can be indicated below each
question and then copies can be run off for each of the
people involved.
This enables decisions to be made known
readily to everyone concerned and in writing.
It is necessary in planning each school building and in
considering the mechanical and electrical designs to utilize
as much as possible local materials and products to minimize
costs and deliveries as well as replacement problems.
In addition, it is always vital to give proper due to the
experience of the existing maintenance staff and local outside
service organizations when selecting and developing the mechanical
and electrical designs.
I would suggest that for example,
in remote communities lacking local control service representatives.
to limit the use of sophisticated central systems and
possibly to apply as much as possible pre-packaged units
which are pre-wired and pre-tested.
In addition, it is
suggested that the institution of teaching programs for
the staff where new concepts in design are being applied
is in order.
In conclusion, it can be reaffirmed that planned coordination
in school design can only be and will only be accomplished
when the team concept encompasses representatives not only
of the professionals such as the architects and engineers,
but also the client who eventually is assigned the responsibility
for establishing the requirements (and authorizing paying
the bills) and the builder who actually arranges for the
construction to take place.
THE IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN by F.W. Woodcock
The subject of this panel discussion is defined as:
THE
IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN.
This title
is acceptable in its present context, but I would like to
suggest to all of you that it could more appropriately be:
THE IMPORTANCE OF COST PLANNING AND CONTROL.
Cost Control appears to mean different things to different
people, but reduced to its most meaningful definition should,
I feel, be taken as the system of control of all costs that
will be incurred in the process of implementing and bringing
to realization any design concept for a school, or in fact,
any building.
Before turning to a detailed review of the cost control
process, it is important to establish the fact that without
cost control, the practical and acceptable equation of
building design to considerations of function, utility and
general acceptability cannot be achieved for the reason
that these basic criteria for any building can only be
ruled as acceptable or fulfilling program requirements if
they do in fact fall within stipulated budget limitations
set for the project.
Therefore, recognizing that it is becoming the practice
for any owner/authority having a requirement for a building,
and in this instance we will consider educational buildings,
to stipulate their need in the terms of a certain number of
square feet of teaching space in one or another of a number
of classifications such as academic, general scientific,
technological, laboratory, commercial, or physical education
etc.
Recognizing that each different type of educational
space requirement can only be fulfilled by the creation of
space suitable to that requirement, the preliminary program
of requirements for any educational building becomes a
prerequisite for the formulation of a cost plan which can
be applied to that building need.
In the foregoing, we have introduced a new term which is
"Cost Plan".
It must be accepted that without a Cost Plan
there can be no effective Cost Control.
13
By the term of "Cost Plan" we understand there being created
a schedule of allawanCes related to the basic plan for a
building which establishes for each element of such building
a unit of gross allowable cost per square foot of floor
area for the erection of that building.
Therefore, in an
orderly progression of events, we visualize firstly that
the authority requirement is defined in the terms of a written
program of requirements identifying the number of square
feet of educational building space required to fulfill
each teaching function.
This program is then transcribed
into a building plan indicating the orderly and thoughtful
layout of a building which will fulfill all space requirements
of the stated program.
When this preliminary planning work is completed, then it
is possible to establish a detailed Cost Plan which will
govern all design, detailing and specifications for that
building.
Such cost plan will take into account all factors
of cost which arise from the location of the building,
availability of contractor organizations in the vicinity of
the building, any peculiarities or difficulties related to
the site of the building, special academic or integrated
requirements which are applicable to the building in order
to make if fit the broader concept of educational policy
and any other factor which circumstances make applicable.
On the basis of the foregoing procedure a Cost Plan is
established for each individual educational building, such
Cost Plan taking into account all factors peculiar to any
one individual building can only be accepted and used to a
limited extent as a basis-for the establishment of a Cost
Plan for other educational buildings having similar
requirements but located in different areas.
In most cases
a Cost Plan must be professionally drawn up to suit each
separate building having regard for factors peculiar to
and requirements for and applicable only to that building.
Despite the particularity of the above definitions which
relate to the establishment of a Cost Plan, there is a valid
basis of comparison of Cost Plans for one building to the
formulation of Cost Plans for other buildings intended to
have comparable functions.
It must however be appreciated
that the adaption or utilization of one Cost Plan for one
building to the. Cost Plan for a similar building can only
14
be undertaken by an individual who
professionally
qualified to recognize the extent of an acceptable similarity
between buildings and the extent to which some provision
must be made for divergence of circumstances or requirements
between buildings.
COST CONTROL:
You will perhaps feel that my previous comments
have, taken a long and devious route towards the subject of
Cost Control, which is the subject of this discussion,
however, I would like to reaffirm to my previous statement,
which was that there can
no Cost Control without a Cost
Plan, just as there can be no law enforcement without
there first being a law.
Therefore, having established a Cost Plan for an educational
building in the form of an identification by statement of
quantity requirements for materials and labour for each
element of the building under consideration, therefore,
we will in our Cost Plan have identified the approximate
quantities of material and labour required of
every sub-trade,
which will be priced in consultation with trade contractors;
all feasible alternatives in the selection of materials and
fabrication and erection techniques will be examined and
final Cost Plan allowances thus determined.
The above mentioned statements of quantities sad costs for
materials and labour will be tabulated and converted to
a total unit of cost per square foot of gross floor area
for each type of educational space required to be contained
within the building under consideration.
The fundamental basis of cost control is then equated to a
summarization of the costs which are allowable on
a unitized
basis for each element of the total building project.
The
control aspect becomes therefore a procedure by which the
process of design finalization through to completion of
construction can be governed in order to ensure that such
detailing, specifying, construction and finishing is performed
in such a way and using such materials as will fall within
the Cost Plan stipulations.
COST CONTROL PROCEDURES:
My talk today would be meaningless
and fruitless unless it were to go beyond the present stage
of stating why a Cost Control program is evolved and what
factors must be considered in its formulation.
The next
question therefore must be, having recognized the need for
Cost Control, how is an architect to accomplish the
establishment of a Cost Plan and subsequent Cost Control
of the design and construction process?
The answer is
obviously the retention of a specialist in this field.
Despite the apparent pragmatism of my previous statement,
I recognize the fact that some architects and engineers
may
have within their organization individuals who are qualified
to prepare realistic and meaningful Cost Plans and also
instigate and implement efficient Cost Control procedures.
Nevertheless, such organizations are few and, therefore,
my following comments must be taken as being primarily
applicable to those organizations who do not have such
capacity within their existing organization.
In cases where it is necessary to design an educational
building within the limits of a stipulated budget then
there are a limited number of courses of actions by the
adoption of which it can be assured that budgets will be
met and observed through the program of the work of designing,
detailing and constructing the building.
I would like
first to deal with the situation from the point of view of
the educational authority, as follows:-
construction process, as by the adoption of this alternative,
there is designated one authority having an all embracing
and comprehensive control of all organizations contributing
to the total project.
1.
At the time a building requirement is determined,
the educational authority has the power to stipulate that
their architect shall be subject to the control and direction
of a nominated project management organization.
Such organization
will normally possess the requisite personnel to compile
realistic cost plans and apply Cost Control measures to
the complete design, detailing and construction functions
without in any way restricting the architect's freedom
in the field of conceptual design and aesthetic consideration
for the building.
2.
The educational authority can at the time of
appointing an architect for any project stipulate that such
architect shall be required to retain the services of
asuitably qualified quantity surveyor for the preparation
of Cost Plans and the application of Cost Control procedures.
It is my submission that by far the most efficient of the
above mentioned alternatives open to an educational authority
is to appoint a project management consultant to control
and direct the entire design, detailing, specifying and
15
IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN by Mr. M.A. MacLeod
The location of your site and the visibility of the school
to the community is important.
This may not reduce the
cost but when the community is helping to pay for it, citizens
like to be able to see and point out a fine building to
their friends.
It is evidant to all that the demand for funds by each level
of government has reached an alarming peak.
Like the
faithful water well being used to it's capacity, the source
of these funds has to have time to replenish the supply.
The people of Ontario are the source of funds for our
discussion here although citizens elsewhere have similar
problems.
If funds are to be restricted, then why not make better
use of the funds we have?
Why didn't we do it a long time
ago?
One of the major advantages of larger units of administration
for school systems recently established under Bill 44 is
the opportunity to look objectively at the educational
needs of a large geographic area.
It eliminates to a large
degree the former competition of small boards setting up
small schools where fancy dictated.
The county system
has built in safeguards by requiring the employment of
qualified personnel who have the experience and knowledge
necessary to assess the needs and recommend the accommodation
required.
This is where cost control begins.
Our topic has been set to discuss the "Importance of Cost
Control on School Design".
I will talk for a few minutes
from the viewpoint of a School Business Administrator.
Cost control, to be effective, should be a factor in the
minds of planners right from the time the need for a school
develops.
Each school system has an educational philosophy
and this philosophy should be reviewed at the time of site
acquisition.
There have been many articles written to
assist boards in making a good choice of sites.
The initial
cost of a particular site in a poor location may be lower
than the cost of one situated better educationally, but
by the time you have added the cost of fill, grading,
oversize foundations and transportation to the less expensive
site, the higher cost of the better site may be justified.
16
Once the site has been acquired, the competition to make
the best use of dollars should begin, not only for the
building but for the yearly maintenance as well.
Too often,
fundamental items such as ground levels, drainage areas
and plans for easy snow removal have been overlooked.
Educators are looking for schools which are flexible enough
to meet the changing needs of society.
Flexibility in
school design should mean:
- expansibility for exterior changes
- versatility for multi-functions
- convertibility for interior changes.
Architects are being asked to build these schools and keep
the cost within restricted limits.
Various factors have
been established.
Metro Toronto uses $20 per square foot
excluding fees and contingencies for site preparation.
Others being in a cubic foot cost of $1.00 and others check
to see that the proportion of the mechanical and electrical
cost to the total job is in the range of 25-32%.
This
establishes a strict competition to produce buildings
within these limits.
Much credit must be given to the
Architectural profession for the success achieved by the
clever use of materials to keep building costs to where thf
are in spite of the rapid increase in the cost of labour.
The cost of education has escalated rapidly in the last
twenty years and there doesn't appear to be much chance
of any let up.
New buildings are still required.
The Ontario citizen is complaining because the bill for
education is increasing and he is demanding that something
be done about it.
Something has to be done to stem the
tide.
The importance of Cost Control on School design
must be acknowledged and enforced.
The Department of Education has been aware of the increasing
cost and as a result has redesigned it's Capital Aid
program.
Some very effective controls have been built into this
program.
It is quite likely that Mr. Spry will elaborate
on these in more detail.
It is evident that school boards are going to be required
to take a critical look at their own programs.
In the more rural area, planners are going to judge the
closing
the two and three room schools and the development
of the central school concept.
This may involve a complex with separate quarters for
Kindergarten to 6, 7 to B and 9 to 13.
It is in this area
of planning that the school system can assist in controlling
the cost.
By setting up a master program for Secondary
Schools, a board will be able to design many special
vocational courses without extra space requirements.
This
was not possible before in smaller units because of the
high operating cost of running these special classes with
low class enrolment.
Now, one area will be able to specialize
in such subjects as data processing, refrigeration or
printing while another would develop electronics and auto
shops and each would operate with full classes.
Maximum use of existing space will help to slow the need
for new accommodation.
Boards should plan their Capital Building program for at
least five years in advance and for reasons other than the
Ontario Municipal Board requirements.
For example they
should try to pace the calling of tenders to a lull in
commercial and industrial developments to obtain a better
construction price.
Getting back to the design, serious consideration should
be given to the use of steel and pre-formed concrete.
If
you have not seen the new buildings at Durham College, it
would be worth your while to investigate them.
It is
understood that these are being built for $10.00 a square
foot.
Who knows, we may be able to extablish an effective cost
control and new design concepts at the same time.
IMPORTANCE OF COST CONTROL ON SCHOOL DESIGN by Mr. W.E. Barnett
1.
GENERAL REMARKS
We must first determine or define cost.
In my opinion
the cost of a school is not confined to the capital
expenditure for construction, if one is to compare school
building costs.
In my opinion cost of a school building
for comparative purposes should be both the capital cost
at the time of construction plus the operating and main-
tenance cost over a reasonable period of time, which should
be a period not less than the debenture period.
No matter how much effort is expended by the architect
on practical cost saving, there are a number of governing
factors that vary from time to time, generally reflecting
in an increase rather than a decrease in cost, and these
are factors over which the architect may have limited
control.
For example, about twenty three contracts in
the Metropolitan Toronto construction industry are subject
to renewal this spring, because by coincidence old contracts
for various trades for various numbers of years terminate,
unfortunately, at about one time.
The current increases
in wages alone being sought vary from 40% to 90% and
negotiations are taking place in the knowledge that just
recently a 73-day strike of bricklayers in Ohio- just
across our international water boundary - resulted in a
two-year contract for the bricklayers in that area to
receive $9.75 an hour, wages only, which is about twice
the Metro figure, and the astonishing figure of $19.50
an hour for overtime, and other trades seeking, and in
some cases getting 100% wage increases.
Schools are not alone in their concern with rising construction
costs.
It is a national problem.
The construction industry
is currently employing "on site" 133,000 wage earners at
17
an average current wage of $135.00 a week:
a payroll
of $18,000,000 a week.
The current situation is that
the cost of labour is approaching about 60% of the cost
of construction, and material, the remaining 40% which
is about the reciprocal of the position of ten to twenty
years ago.
2.
WHERE IS THE INDUSTRY HEADED
One could talk at great length on this subject, but briefly,
the general contractors are rapidly becoming brokers
maintaining only administrative staff at headquarters,
and key personnel, superintendent, carpentry foreman. etc.
on their permanent payroll, all other labour being hired
from hour to hour, day to day, from union sources
as the
need arises.
There is little reason to select a general contractor,
and in most cases a sub-contractor, because of the capability
of his "on the site" staff since the contractor at
any
level now has limited control over the "on site" workmen
that he will employ.
As a result of all of the above general remarks, to which
many more could be added, there is a trend towards
industrialization of the construction industry, with
large component parts of a building being made under the
controlled climate conditions of manufacturing plants and
delivered to the site to be hooked together with a
minimum of on-site labour.
The S.E.F. program in Toronto, the C.L.A.S.P.
system in
England, both of which you are to hear more of later in
the program, and the many systems in the United States
are simply the industrialization of the construction industry
to one extent or another.
This does not mean that every
community has to embark on a S.E.F. or similar
program.
The Metropolitan Toronto experience has emphatically
indicated to industry the benefits of development of
system or component part construction, and I will be very
surprised if industry does not pick up the torch from there.
3,
RESULT
As a result of the above, which I again emphasize
are
only a few highlights contributing to the background in
the change in the industry applicable
to other forms of
18
construction as well as schools, there is the potential
of some favourable as well as unfavourable results.
For
instance, standardization of large components of construction
units will limit the opportunities to exploit site topography
and other possible natural resources of the site.
The
opportunity to add a foot here or there, or make modest
changes in the outline of the building will be lost.
Large
changes may be possible, providing they are in accord
with the large pre-manufactured units of construction.
Therefore the program of needs will have to be developed
to a precise and final conclusion, and once construction
starts additional thoughts will have to be saved for the
next building program.
On the credit side of the ledger, there could be a great
deal more flexibility in the internal layout of the building
because removable and portable types of area segregations
will be used, permitting the building interior to change
with the changing teaching techniques and aids with little
if any cost.
This will all result, of course, in a
controlled and similar environment throughout most,
if not all of the premises.
This is another subject on
which one could spend the entire allotted time discussing
the potential advantages and disadvantages.
To control cost in school construction today under all
of the above background circumstances, therefore, the client
and architect must work even more closely together,
particularly in the initial stages.
4.
HOW CAN THE CLIENT HELP
It will be even more important for the client to benefit
from the architect's advice in the selection of a site.
There will be limitations on the compatibility of pre-
manufactured units to unusual site conditions.
I 'lave
always believed that the architect s...uld assist the board
in the selection of a site.
I can always recall a board
visiting a site for a school with me and wondering at my
dismay when I expressed some concern over the healthy
growth of bullrushes over the area.
It will be necessary for the client to organize his academic
requirements not only in respect to space, but also in
respect to philosophy, the openor soft plan versus the
hard or inflexibile layout.
It will also be necessary
for the architect to have
a knowledge of the client's
approach to teaching techniques and
the type and extent
of teaching aids to be employed,
and to be catered for
by the physical plan.
An architect's fee is a constant
factor, being a percentage
of the cost of construction, and
it is in the client's
interest, therefore, to provide
a reasonable production
time for the architect, permittinghim for that same fee
to develop to a finer degree with
the client a building
to better satisfy the function for
which it is being
constructed.
Though an architect cannot
guess the trends
of the market any better than the
client can guestimate
the fluctuations of the stockmarket, it is the responsibility
of the architect, within
reason, to build within the
confines of the client's budget.
It is the responsibility
of the client to present the
architect clearly and concisely
with the budget, and if there isany disagreement as to
the ability to provide the needed
accommodations for
the budget, it is the architect's
responsibility in the
initial and development stage to
so advise the client in
order that adjustments can be made
without a great loss
of time and effort on everyone's
part.
At this early stage it is notunusual to talk in terms
of square foot costs.
This can be hazardous, and it
is
essential that each party know
precisely what is to be
included in the costs.
The client should advise the
architect on his policy in respect
to stand-by equipment
and sophistication of operation.
This varies greatly
from board to board, and what
one board considers adequate
another board would consider
very inadequate, and this is
one of the contributing factors that
makes it difficult
to compare one school with another
on the basis of square
foot costs unless one knows
precisely what the square
foot costs include or do not
include.
The client can help the
architect and himself by advising
of any pet requirements and
standardization of equipment
that may be desirable in
a school system, particularly
in respect to servicing and
repairs.
It is also most
important that the client advise the architect
after
proper consideration of the expansion potential
of the
building to be built.
So often a board will say that
a building will do for the next fifteen
years, and the
architect finds himself back on the site
in less than
five years.
This costs the client a considerable
amount
of money, as expansion facilities
should have been built
in at the time of initial construction
at a lesser cost,
avoiding the tearing down of walls,
ceilings,
floors, etc. in order to provide
services and unforeseen
interior alterations.
Again, limitations prevent
a continuation of this subject,
but I am sure that you get the
general trend and can add
many more relative items yourself.
5.
HOW CAN THE ARCHITECT HELP
It is important that the architect have
a thorough knowledge
of the "School Business Procedures
Manual" to take maximum
advantage of the Provincial grant
that can be obtained
for the academic requirements of the
building project.
There are many ways in which
care in this can work to
the benefit of the community.
It is important that the architect be
up to date on construction
cost trends and forecasts, not onlyto keep the client
advised of realistic estimated
costs, but to take advantage
of seasonal and other construction
fluctuations in the
market.
It is important that a project be
out to tender
in a competitive market.
if three or more tenders
are
being called at the same time, the
competitive situation
and the interest and time of the
contractor that can be
afforded to the tender can
vary considerably.
A well
considered estimate by a contractor
is usually a better
estimate.
It is important for the architect
to be knowledgeable
on the degree of sophistication in boththe design and
operation of the building.
Usually such sophistication
costs a considerable amount of
money.
We have one school
where the principal, by pressinga button on his office
desk, can read the temperature of
every room in the school.
This is but one example of
many operational facets that
19
can be built into the school, but often at considerable cost.
The architect should be thoroughly familiar with the
building by-laws of the local community in which the project
is being constructed.
A thorough knowledge of the
requirements of the Fire Marshal's Office of the Province;
the Health Department of the Province, and other bodies
with jurisdiction over the construction of the project
can work to the client's advantage.
It is important to
work with, and not against Government departments.
Government departments are anxious to assist in developing
economic solutions to building problems and, of course,
still complying with the requirements.
It is important to design to suit the need in scale with
the use and occupancy of the building or a room in the
building.
For instance, it is not unusual in an elementary
school to find the room with the greatest ceiling height
to be the kindergarten, which accommodates the smallest
people in the building.
It is important that the architect provide a cost estimate
on a square foot basis at the schematic stage of the
building development, with more accurate estimates being
provided at the preliminary stage of the development,
and an estimate based on quantity take-offs during the
working drawing and specification stage, at which time
the client should be advised of the cost picture, and
if the client has been requesting additional space or
-making changes that are adding to the cost, the client
should be advised at the time he makes such requests during
the development of the working drawings and specifications.
The client should be informed of the services of the
quantity surveyor, particularly where budgets are unusually
restrictive or where some unusual local conditions
or
unusual nature of the building proposed may demand unusual
caution in cost estimating.
Either this architect or the
client should provide a reasonable and practical contingency
allowance, and each should be knowledgeable that
proper
provision has been made for unforeseen site, building
or
climatic conditions.
20
It is important that the client be kept informed monthly
during the construction program on adjusted contract amounts,
with written change orders issued monthly.
It is not good
business for either the architect or the client to complete
the construction and then find a considerable list of
unexpected additional costs.
To effectively do this, the
architect has to impress on the general contractor the
need for monthly accounting, and the contractor in turn
has to let each sub-trade know that additional costs will
not be entertained for extra work after the work has been
completed.
It is important that the client be informed on the materials
proposed to be used in the construction, with a brief
explanation as to why particular materials are selected
and their particular effect on budget.
It is important
that in a project of modest budget the dollars be spent
where the need is greatest.
One of the most important responsibilities of the architect
to the client is to inform the client precisely as to what
basic services are provided by the architect in the fee
he is charging.
The client will then know whether additional
services of consultants are required, and to what extent.
There are no doubt additions that can be made to Lhis
list, but if consideration is given to all of the above,
cost control and cost savings can be Provided for a
building project, and the chances of a happy relationship
between contractor, client and architect can be experienced
at the completion of the project.
6.
CONCLUSION
The architect has a right to expect a client to have a
reasonable budget, and if the budget does not seem reasonable
to the architect the time to make this known is at the
beginning of the project and not after tenders have been
called.
The Client has a right to expect the architect to live
within an agreed budget, subject, of course, to moderate
and reasonable tolerance.
Good design does not command
high costs.
Reasonable cost, however, demands good design.
If a client has a good client-architect team working for
him - keep it:
it will work even better with repeat use
and familiarity.
HARD AND SOFT SCHOOLS by Mr. R.G. Rist
Today's educators are constantly bombarded by an increasing
number of pressures created by other professional educators,
by a host of anxious amateurs, and by ever alert opportunists
who realize education is now big business.
The educational
field is filled with idealists and pragmatists, traditionalists
and innovators, opportunists and martyrs; all have a part
in shaping education.
We are being inundated by a multiplicity of educational
trends and innovations which become popular, and lose
popularity, as often as the fair sex's migratory hem line.
Many of the trends and innovations of today are resurrected
trends and innovations that some of us have experienced
before.
It is increasingly difficult not to believe in
reincarnation; certainly you often feel that you have been
here sometime before.
Some of the more clearly identifiable trends that characterize
education in North America and Europe are:
Uniformity of curriculum to individuality of curriculum,
Required sot of courses to more electives,
A time unit of one year to semestering,
A graded to a non-graded approach,
Discrete disciplines to subject clusters,
A stress on content to a stress on processes,
A sequential approach to discrete units of work,
cognitive to the affective
Emphasis on past to an emphasis of the future
Adult-determined curriculum to a student-determined
curriculum.
If you superimpose a variety of modes of learning,
a bewildering
array of educational hardware, and a growth- constrictive
budget, on the recognized trends, then it is obvious that
all of us who are involved in education, either intimately
or peripherally, must become masters of compromise.
Using
Anthony Barton's Hard-Soft School concept, I would
say that
21
each of us needs a hard-soft approach to the whole business
of education.
We will always have educators assuming positions of extremes
which will be reflected in a completely hard, oz completely
soft, concept of education, It takes a considerable amount
of intestinal fortitude to maintain a position that in-
corporates the best of traditional approaches to education,
melded with carefully selected innovative trends.
It is so
easy to move from one caricature of learning, typified
by all that denotes "hardness", to another caricature
embodying "softness".
In the Province of Ontario, at the
moment, we have schools that range from one extreme to
another.
This, I maintain, is a very healthy sign and it
is in this kind of environment that authentic innovations
and trends of substance begin.
Individualization of approaches
to learning by school systems or individual schools, is
itself a necessary part of a hard-soft approach.
It is
no more viable to dictate to a school or a system, a.philosophy
of education, than it is to dictate to any child what he
must learn.
Educators must always have the privilege of
deciding where on the hard-soft scale they wish to pattern
the rationale of that part of the educational system in
their care.
When educators are criticized for indecision in establishing
a clear-cut direction, and in developing a curriculum to
reflect that direction, I believe that this is a healthy
sign also.
It is too easy to accept all that is recognized
as new and innovative with total, or at least partial
disregard of aims and objectives.
The school or system
that embraces all that is new in its curriculum assumes
aposition just as untenable as that in which nothing new
is ever considered.
There are situations developing in
North America where the school develops an admirableprogram
incorporating subject promotion, individualized learning,
student-selected curricula, but at the same time, incorporates
a high degree of permissive behaviour on the part of staff
and students.
At the risk of sounding heretical, I fail
to see how extremes of permissiveness with no rules and
"no holds barred" has to be a necessary adjunct of
a progressive
curriculum.
In a school with no rules, even the "Golden
Rule" goes out the window.
A school of this type is moving
to the extremely "soft" stage, to become a flaccid, amorphous
mass with little purpose except to please all, at all times.
22
I see no time in the future during which anyone concerned
with education, whether it is the designer of the school,
the supplier of hardware, or the provider of learning
materials, can make an assessment of a trend, "gear-up"
for it, and then sit back complacently while the blue-print
goes on servicing for many years.
It is unquestionably
cheaper to make ten thousand copies of one original Paris
dress creation, than it is to make ten thousand originals.
It is most obvious that any design whether for a building,
a book, or a curriculum, when repeated many times, becomes
economical in terms of money, energy and ulcers.
However,
if I may stretch the dress analogy a step further, any
lady is skilled at taking the simple basic black dress and
making it suit any occasion.
I think we must become more skilled in recognizing the basic
garment in education and become less prone to losing sight
of it as we pursue the development of the decorative devices
of the garment.
The support forces for the educator have always tried to
be completely aware of the philosophy, aims and objectives,
of each school system before providing the supportive
services, but it is imperative today that the supportive
forces reflect the same flexibility of approach that is
charcteristic of most sytems today.
Supportive services
have an awesome effect on educational trends.
So many
curriculum builders spend millions of dcllars to produce
highly sophisticated-package deal which the educator is
expected to purchase, and implement in its entirety;
publishers spend small fortunes providing learning materials
which of economic necessity are expected to last several
years.
Designers of school buildings develop designs to
reflect trends and then do such a good job that the design
tends to maintain the trend, or shape it further.
The most clearly identifiable trend in education that is
visibly evident in school-design, is the no-wall trend.
The design is intended to facilitate the open-concept
learning situation with a variety of student and teacher
combinations.
But there are not many schools of this design
that have developed the learning situation as intended.
The
mental walls still exist, aided and abetted by the well-
placed set of shelves, planters and cupboards.
Should we
pursue, for many years to come, a trend that has developed
excellent school designs and relatively weak schoolprograms,
or should we await until more teachers are skilled in the
new situation, or for that matter, want to teach in such
a situation?
Should we wait until some sort of assessment
tells us that the approach is so good that
we should pursue
it in greater numbers?
I feel that the no wall trend should resolve itself into
a direction better suited for the individuality of students,
teachers, and communities.
Just as the fishbowl existence
of apartment dwellers is found to be considerably wanting
in certain social aspect, I suspect that countless little
bodies scattered over acres of broadloom has certain social
shortcomings.
I wonder if the concept of a school of fish,
or a school of children started first?
Even fish like to
be alone sometimes.
Open spaces and intimate closed-in
areas are surely necessary for all human beings at all age
levels, and could become the "basic black dress of school
design".
Each of us must become aware that most educators are not
going to move philosophically from a hard position in
education to a soft one, but instead they are going to
develop positions anywhere along the spectrum.
All supportive
services must realize this may be disturbing for the
programming of such services for any length of time.
Within the allowable limits of financial necessity and
professional integrity, supportive services must accept
the fact that educators will be constantly seeking to provide
the best possible education for every child in the province.
The only thing that is becoming the same or equal in
education, in any sense of the word, is the equal opportunity
for every child to get the best possible education.
HARD-SOFT SCHOOLS - WHY FLEXIBILITY? by Mr. J.K. Crossley
I'm going to base my few remarks this afternoon
on ona
dimension of the school only - I've seen so many schools,
in so many places, that the secondary importance of the
building is something I take for granted now, as I
see
successful programs for students in quite unprepossessing
environments, and beautiful testimonials to designer skills
housing activities that can barely be termed educational.
But having said that, I've really criticizedmy own kind
in education, those who plan programs, who
prepare teachers,
who think about the nature and purposes of the educational
process in a school.
We've rarely made clear statements
when asked to do so by the designers of schools
- we often
speak with many tongues
- the generalist, the specialist,
the child-centred, the academic, the technician, the
elementary, the secondary, and so
- a babel of opinion,
each convinced of its own correctness.
I want to try and tie together as many of the loose ends
as I can, to look at the school in a more basic dimension,
and in that dimension, we might find
some clues of use
to designers of environments for learning.
I'm going to
turn to a fairly old idea and to the work of Joseph C. Grannis
for my basic theme.
Professor Grannis is head of the Divison of Instruction
at Teachers" College, Columbia University.
He has written
a paper called "The School as a Model of Society", and
it is basically his point of view that I
am using here,
although I am adding my own basis, of
course.
Essentially, Grannis reminds us that a school represents,
to its students, a model of society.
In the patterns of
behaviour of students and teachers, "in the authority and
decision-making structure of the organization, in theways
that people talk with one another, learn and work andplay
together" - in these ways, and more, a school teaches
students about society.
23
He says, and / agree most emphatically, that it is the
structure of the school in these dimensions
- of organization,
of status groups, of implicit behaviour rather than
overt
behaviour
of "the little things" so accurately gauged by
children, the tone of voice
the loudness of the bell, the
remoteness of the principal - it is in these dimensions
that students learn about society.
And then Grannis tells us of the models thatwe have
unconsciously been using for our schools
- for rather than
the educator formulating a societal model for education,
and incidently, for the buildings to house that model
of
society, the educator has adopted instead the patterns
of
the most pervasive and basic institution in society.
We are just now coming out to the stage of using the factory
as our model for the institution called "the school".
We
are moving away from the use of identical grading standards
and from the use of "assign and recite"
as the standard
lesson.
We are questioning the value of failure, the
discarding of those units that don't meet the standard,
in
factory terms.
We are questioning the value of repetition
of a dull and endless nature.
Now, in special education, we are even questioningthe
removal from the production line of individuals
who fail
to meet the laid -down standards.
We now urge the integration
of handicapped kids in non-graded classes,
especially.
Competition, of course, is encouraged in the factory
school.
Rather than quality of work or individual initiative
though,
it is competition in quantity and speed that is
rewarded -
provided the line is not upset by someone doingnext year's
work.
Authority, often paternalistic, sometimesworse, characterizes
the factory school.
The directives of superiors must be
listened to.
Time is used as an important element of
control - regulation of time is essential
to keep production
moving.
So too, is regulation of space
- students must
"stay-put" in their stations, or disruption
might occur.
As one visitor said when he saw
a suburban egg-crate school,
the typical factory school can be viewed
as a lower-class
joke on the middle class.
24
Then Grannis moves on, and suggests to us that we are now
busily adapting our schools again.
My references, as do
his, apply to both elementary and secondary levels.
We
are adapting to a new model, and this time, it's the
corporation from which we are getting our patterns.
There is now to be co-operation planning by teachers.
More
rationalizing of actions takes place - it is called Program
Planning and Budgeting Systems in industry.
PPBS Objectives
are stated and flow charts and statements of goals are
prepared to govern action.
In schools, we call it team
teaching.
More specialized materials of instruction are now employed
in the corporation school - special aids are often developed
by teachers themselves.
More specialized equipment is
used:
projectors, computers, tape recorders, head sets
- the new tools of the corporation.
There is quite a hierarchy in the corporation school
- of
principal, team leaders, department heads, teachers,
teacher aides, and finally students - with various degrees
of authority distributed up and down the pecking order.
It is not yet obvious, but soon will be, in my opinion,
and in Professor Grannis', that students have even less
real say in what happens to them in the corporation school
than in the factory school.
So complex are arrangements
that must be planned ahead, that little room is left for
accommodation to changed needs or altered circumstances
among students.
Timetables are too complicated to change,
plans are too involved to be altered
or the programmed
material is in print and can't be wasted!
But the third model that Grannis puts forward is not
entirely satisfactory either, for while it is most appropriate
in the primary years, it is apparent that the family model
of school is not realistic as children become older and
closer to the institutions of adult society.
And yet we
find the pervasive patterns of the factory still govern
many primary and junior schools - I recently saw an open-plan
school with a production line operation based on standardized
textbooks and uniform final examinations that completely
negated the potential of the building.
The interpersonal
relationships of the family and the pursuit of the interests
of the pupils as starting points into the sub-disciplines
of knowledge must be characteristic of all schools
-Kindergarten to Grade 13.
I do see, however, that in the
Intermediate and Senior Divisions, more organized activities
need to be carried on - something like the kind suggested
in "Living and Learning", and along the lines suggested
by the Minister of Education in his announcement concerning
the reorganization of secondary schools last week.
In summing up these very general remarks, I'd just like
to remind you that the factory model has been with
us, the
corporation is developing swiftly, but my hope is, that
with luck, foresight and considerable effort, we'll be able
to push right on through to a new dimension of educational
organization where our organizational patterns, and our
buildings, will reflect our concern for the individual and
his needs.
We must plan ahead, we must have Program Planning
and Budgeting Systems, we must have some measure of
coordination in schools, some degree of timetabling, joint
planning, and so on, but we must be sure to leave elbow
room for each student and teacher, for each individual to
be an individual.
Buildings must not lock in any one
institutional model.
Perhaps the geodesic dome is really what we should builds
!So
The
run
-of-
the-
mill
sch
ool i
s ha
rd, i
t is
a pl
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for
hard
chi
ldre
n an
d ha
rd te
ache
rs,
plac
efo
r pe
ople
vrh
o lik
e to
be
clea
n, e
ffici
ent,
orga
nize
d. V
ery
hard
peo
ple
do w
ell i
n th
e no
r-of
-the
-mill
sch
ool.
A In
sesc
hool
isso
ft, it
is a
pla
ce fo
rsof
tchi
ldre
nand
soft
teac
hers
,apl
acef
orpe
ople
eho
liket
obeh
lthy,
mm
e-go
ing,
Mw
iredV
wys
oftp
eopl
edow
elle
Mee
sith
ad.
Mos
t peo
ple
are
neith
erwry
had
nor
eery
sal
t the
y do
not
do
wel
l in
any
scho
ol.
Let a
s de
sign
sch
ool w
here
eve
rybo
dy w
ins.
Har
d te
ache
rs, s
oft t
each
ers,
her
d ch
ildre
n,so
ft ch
ildre
n, a
nd a
ll th
e pe
ople
in b
etw
een.
A s
choo
l _w
hich
giv
es a
chi
ld a
cha
nceto
expl
ore
a fu
ll sp
ectr
um o
f peo
ple
and
of e
nviro
nmen
ts.
TH
E H
AR
DSO
FT S
CH
OO
LA
ntho
ny B
arto
n25
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Tr
seri
sem
is
Mad
sad
sob
hi e
gad
mem
oD
er b
end
sad
sob
ban
dab
mir
sasy
m b
ulbre
ad b
e pa
t of
arer
eset
spri
tes
A a
mp
or. c
irri
spo
w s
ages
err
mon
t of
wee
d.sk
is e
ndsa
dieS
ior
'As
an e
ater
holy
so
posh
dm
infr
estio
m M
el b
eide
des
scho
ol a
rose
dm
infa
msd
oe le
nd la
the
tele
ados
sosk
ed
flei
dlah
ry.
tam
mar
kPr
msa s
crew
wrs
eere
. tle
sa
'ger
msw
ish
ai*
th d
dks
Cem
spee
s es
tair
er w
ith th
e im
arbe
tdoe
to b
urre
spos
ame
asso
ess
sad
ham
ar*
bet a
rbbe
led
atom
is th
eit s
choo
lrap
e C
hars
asl
ant
mat
drI
by c
asol
edea
s u
eem
itiar
t sas
sesd
esel
d be
Ise
arie
rt
thes
sins
d ro
cket
s. s
s ov
a es
are
a pr
efee
dena
ls.
Nem
, tel
embe
,m
ense
s sa
di n
ebae
logi
s Sc
ald
to r
id to
art
y ou
t pea
of I
rk w
ank
isoh
. sch
ool s
esta
sses
s w
hen
dry
aft i
sms
wkb
doe
dar
ks I
ds. w
illde
w b
oth
way
s.
Lik
a w
ith o
hs s
aid.
Cha
irs
Am
id m
ilk, t
ot s
otla
elto
orom
to o
n
ruse
diet
s pr
os. T
heir
sch
ool s
houl
d ba
p rh
o at
erra
ky.T
hey
trar
der
shou
ld ta
rry
cot m
onie
d pr
ojec
ts e
tch
se th
e re
liefo
f dr
mid
dy o
r th
ehy
ing
of s
choo
l stw
essi
pa. C
hile
s re
d le
yrs
kw
tear
sad
pow
ersa
ssie
r ol
ds s
a th
e in
Ann
so
dim
s th
e le
ss a
kar
toSs
are
of
the
Ada
ir. e
t dr
Item
se
imbe
d pl
ans
la e
asse
te.T
hey
ste
sully
Wed
by
cood
octo
d to
ot*
to A
ttslt
they
In
sore
obe
emon
, thl
yto
ishm
Cos
s:po
w &
Seel
Bar
Mem
bas.
Tho
r ar
kM
idas
mas
t be
esM
are
to s
assi
ness
teis
h be
low
to w
ith o
deet
tsp
ends
sam
pans
se d
o pe
as&
PRO
POSA
L: T
he s
hod
sher
d ho
am
iss*
sad
bal
kw
ish
phyd
uDy
bed
as h
ors
toea
rls
bans
edie
s sa
te w
ild tw
o fa
rM
e a
phyd
esly
sea
ans
.A
base
-Way
, re
shoo
t mig
ht a
ssis
t air
ed, s
at s
adbo
anm
elis
es m
edal
s
fapr
ess.
The
Ida
. b to
ese
boiy
In
the
drip
sam
ples
spo
nssm
of
esat
esse
ssr
to k
ip W
Y I
ons
boom
hoo
k'. m
nraw
mai
neaf
fect
his
red
wha
t b d
ot
As
hunc
hes
wee
sas
s so
br:
ea
lerr
yshi
s pa
tas
beds
it ra
ms
toco
b sr
, had
sim
anw
es, s
uch
se r
olab
lat t
eam
s sa
sssa
d Sa
abta
rs h
as to
be
mea
d ot
will
The
Iw
ildra
*Id
Inss
tork
of
pow
er s
adto
rpor
s. ta
d It
o re
pot *
boa
toot
hed
odd
mar
of
wee
d.
Whe
ts p
ossi
ble.
the
vii r
ay b
e ss
aade
d ap
sad
doss
the
wai
ls, t
o pi
ssro
ar f
inal
ity to
dm
yes
as
a *b
ola
The
re 'b
oob
be p
ower
sad
soe
stss
okst
ioa
outle
ts a
ray
huss
atio
a of
the
SHU
R I
S T
HE
MIN
DC
IRC
O. A
ND
WIS
ES
The
har
d -s
eit
vAilL
t law
41.4
::
HA
RD
tlsp
iked
iron
rai
lings
ASP
HA
LT
PL
AY
GR
OU
ND
in w
hich
pla
y is
forb
idde
n
All
-el
ectr
icst
erile
il!E
TT
CH
EIt
chai
rs,
GIR
LS
IliM
akom
Cig
aret
te%
RO
OM
ST
AM
P
smok
e, a
ndco
pies
T
Iden
tical
DIN
ING
RO
OM
etc
dosing
rostrums
win
dow
s w
ith ir
on g
rills
rvAcums
PAM
AUDIO-
With
port
raits
of
VIS
UA
L
past
pri
ncip
als,
STO
RE
lists
of
scho
lars
lock
ed
GL
IAM
IIIG
CO
RR
IDO
R li
ned
with
lock
ers
of s
teal
Lat
inti
ft00
0tC
ompu
teco
ntro
lled
envi
ronm
ent,
OPT
ICS
TO
LO
CA
L L
OA
MY
,C
OM
MIT
S R
OO
M
free
acce
ss terr
inal
info
rmal
catk
iLg
and
eatin
g sa
ne
MIC
E
blac
kboa
rd, g
reen
CL
ASS
RO
OM
with
row
s of
iden
tical
desk
s,
OT
YIC
E
DO
TS
LIS
SAlif
Study
carr
els
Boo
kscl
assi
fied
by 'W
aite
r
Sooh
lle
TO
CO
ND
I= T
OM
SG
YN
. TIM
M V
IEW
S
cast
sal
star
t
roof
ends
func
tionl
ess
le
scaf
fold
ing
10* tram
was
arap
viss
evo
IND
IO S
i
SOFT
27
The hard-soft idea can take many forms. It is
an educational
suggestion, not an architectural one. In the han.ls of
a good
architect, surprising things might cane of It.
28
An intermediate zone seems to be an inescapable
part of a hard-soft system.
In this zone, hard
structures, such as television receivers,
screens and thumb tacks, have to be moved at
will.
This requires a rigid framework of
power and support, and we suggest a hard
over-
head grid made of soft wood.
Where possible, the grid may be extended
up
and down the walls, to give greater flexibility
to the area as a whole.
There should be power and communication outlets
at every intersection of the grid.
L
I :
fib
alli
,T11
111 s
The
fin
al p
air
of p
hoto
,'"
" 1
11T
wo
scho
ols
built
hal
f ce
ntur
y sp
ort
-:24
m41
iShi
ch w
ould
you
lay
we
the
herd
er?
Kee
p yo
ur a
d of
f th
e et
=
WH
ER
E I
S T
HE
CO
MPU
TE
R I
N T
HE
HA
RD
-SO
FT S
CH
OO
L?
IT H
AS
TE
NT
AC
LE
S.
It w
ould
be
deal
t. to
dre
w d
ear
boun
dari
es b
etw
een
hard
, int
addi
ate
sod
sok.
The
com
pute
r its
elf
mig
ht b
an to
be
situ
ated
In
the
bard
nin
e, b
utte
rmin
als
coul
d be
pla
ced
in b
oth
thee
bud
and
the
inte
rmed
iate
sod
. Atf
tlIdd
li a
cam
mig
ht e
ven
&a
be w
ry in
to th
e so
ft n
one:
that
wou
ld b
em
ilest
one
in M
entio
n: a
com
pute
r te
rmin
al in
the
mud
.
The
term
inal
s in
the
HA
RD
tone
are
use
d fo
r om
arth
atio
nel w
ork,
reco
ed.k
eepi
ng, a
ccou
ntin
g, b
udem
inek
dee
ding
. (T
here
may
be
two
coop
ed in
the
com
pute
r ro
om, o
ne f
or th
is k
ind
of th
ing
and
one
bat
educ
etio
nal w
ithT
he te
rmin
als
tbeson'
tune
see
use
d fo
r fr
eein
tera
ctio
cs w
ith th
e 's
talk
s, in
dmer
ibab
le.
The
term
inal
sbe
the
INT
ER
ME
DIA
TE
none
are
date
din
ato
mpr
acte
outn
aled
env
iron
men
t. E
ach
term
inal
sits
632
roo
m o
f its
ow
n an
dth
e co
mpu
ter
cont
rols
the
light
ing,
sta
nd, d
ell a
nd ta
rt&
=fa
ces
of W
e1C
OR
L
BR
IER
S A
RE
NO
T E
NO
UG
H
Mem
wou
ld h
appe
n if
hard
eork
sch
ool w
ere
bat a
nd O
wed
In
the
bade
of
teac
hers
who
did
not
und
erst
and
kt T
hey
wou
ld to
rn th
e fl
exE
sla
kid
into
asy
mna
km, t
am e
lect
ric
bells
ont
o th
e va
s, r
emot
e th
e Ju
nk le
vel t
he m
ud,
and
put o
p di
ns e
ying
BE
EP
OPP
THE
GR
ASS
. It's
bard
life
.
So w
e co
ed n
ew a
dd f
or f
lew
don
* Pe
ople
de
ten
thaw
det
hte
ethi
ng to
mat
ch d
sck
surr
ound
id, a
nd d
o it
al d
ay. A
n da
re f
lexi
ble,
then
dem
d ad
d w
ho c
an s
plic
e ad
eam
pe, d
ilate
s th
e do
msc
icas
and
clim
b tr
eed
Yen
then
are
goo
d m
acho
s.
PEO
PLE
AA
E N
OT
EN
OU
GH
Goo
d te
ethe
s. e
xist
, but
they
hav
e fe
w s
choo
ls w
orth
y of
them
. Tho
se th
atst
ay in
cam
bial
teed
to ta
ke o
n sl
owly
the
dupe
of
the
hard
-wal
ed m
ould
.
BU
ILD
HA
RD
SOFT
Giv
e th
an th
e ac
hook
res
t tee
thin
g ne
ed.,
Ham
den*
mill
net
do.
The
re is
at p
rod
tren
d to
war
d et
raill
exib
ility
.bid
s is
dec
eptiv
e in
that
it b
an
ande
mst
ral a
new
but
not
an
aduc
ador
al m
an T
iara
is li
d to
he
mid
for
mal
ls m
il if
is o
ut b
e m
owed
onl
y by
teac
her.
Mov
ing
de is
odd
=ch
ildre
n le
d de
n th
ey n
eeni
pula
t. th
eir
MA
tre1
B.1
1$11
1012
0aV
eq,U
MW
*th
ey w
ent t
o do
so.
We
wel
com
e yo
ur c
omm
ents
, add
ed e
nd to
ggat
ions
add
ing
the
idea
spu
t for
war
d in
this
phi
loso
phic
al p
apa.
Wri
te e
n te
leph
one:
Dep
arte
d of
Com
pute
r A
ppik
atio
ue, T
he O
utdo
Indi
um f
oe S
teak
s be
lasc
etio
n, 1
02 B
lom
Str
eet W
ed, T
oron
to 5
, Om
ni..
Can
ada.
Tel
epho
ne: (
416)
921
6641
, dem
i= 5
24.
HA
RD
spiked iron railings
imposing
TA
FFR
OO
M
SPACIOUS HALL
with portraits of
past principals,
lists of scholars
CL
ASS
RO
OM
with
rows of identical
desks
.d
D/N
IR
OO
M
Learnin
Room:
Compute
controlled
environmen
sterile
AUDIO-
KITCHEN
VISUAL
STORE
locked
free
access
tersdna
m0,
tr cco
et
O. 2
2
00.
H
a O 8 O
OFF
ICE
CO
MPU
TE
R R
OO
M
b10
1 XA
tet
povv
riph
011
poin
tS
ere
.e01
4tei
el
4,11
.era
SA
tt.' S
OF
HA
RIN
SOFI
ED
UC
AT
ION
: P. R
EA
DIN
G U
ST
HA
RD
Cid
er 1
4O
ntar
io D
epar
tmen
t of
Edu
catio
n(C
lad
docu
men
t of
edad
onal
lest
reau
ency
)
The
Rep
ublic
rum
(The
Wm
of
cont
rol t
oba
sis
for
educ
atio
n. D
ip in
to B
ook
Tw
o en
d w
atch
the
educ
ator
sew
ing
lidow
s. d
entin
gst
ate
myt
hs a
nd m
ould
ing
the
th.t.
L. M
ae d
d.)
The
Che
epin
g Sc
hool
Osa
ka:e
rnC
oedi
ted
(A s
peci
men
fro
m th
e on
o of
line
d w
hich
acc
epts
the
Idea
of
cont
rol
blin
dly)
Tea
chin
g D
isad
nuas
pd C
hild
ren
in th
e Pi
t-SC
h001
(The
ides
of
cont
rol c
arde
d to
ext
rem
es)
Prog
noun
ed I
ndic
tion
and
Edu
cate
d T
echn
olog
yJo
urna
l(C
omai
dard
of
the
bard
rad
on b
y m
yth
and
Jers
on)
Wal
den
Tw
oSk
inne
r(A
nov
el b
y a
beha
vior
al d
ied
saw
ed d
irec
t con
trol
)
SOFT
Stun
roct
inE
Nell
(Acc
ount
of
a (m
e sc
hool
for
ty y
en o
ld, b
y Ir
s he
adm
aste
r)
Thk
seps
is is
Abo
ut d
ada
Jade
d(A
mou
nt, o
f T
oron
to'.
own
free
sch
ool,
Eva
de)
Roc
hdal
e C
olle
ge C
alen
ds(F
ree
educ
atio
n at
the
univ
ersi
ty le
vel)
Wal
den
Tho
reau
(Lif
e in
the
Woo
ds s
e a
philo
toph
ical
idea
)
Can
adia
n Pe
te e
ra.
(Rum
ple
of u
nder
grou
nd p
apa
pedd
ling
the
free
life
m p
op)
INT
EPA
SED
IAT
E
Ids
dw
iden
s H
urle
y(R
elen
ted
eddi
ed th
roug
h ex
peri
ence
be
did
Und
anun
ding
Med
iaM
aned
McL
ella
n(H
ood
ford
edg
ed d
ance
d by
sof
t TV
mid
den
in th
e bu
d)
Mhu
nden
tand
ing
Med
iaG
ordo
o M
onk,
Nat
kael
Fan
s Po
d,(
A p
aper
poi
ntin
g ea
t how
the
hard
sch
ool d
am th
e m
edia
)
Em
ileR
oom
ed(T
he I
des
of a
llow
ing
the
did
to L
esko
fre
ely
in a
Id
Ltd
)
Lar
d of
the
Plie
sG
olds
(Nov
el s
hoot
!dr
ead
dam
n th
row
n In
to a
sof
t and
rone
nna)
ovet
da
OV
ER
VIE
W
SEP
Rep
ort a
The
Met
ropo
litan
Tor
onto
Sch
ool S
od(S
tudy
of
Edo
cale
ed r
ealit
ies)
(Qom
." f
rom
dem
rat
oed
ema
for
bird
er r
eadi
ng)
29
THE HARD-SOFT SCHOOL by Mr. W.A. Strong
The architect is experiencing the change in educational
philosophy in a most pronounced way because he is building
the New Schools.
These are the schools where new ideas
and techniques can be better put into practice because the
surroundings are developed to suit them.
So from my point of view, the battle for
a more flexible,
relaxed, humanistic school has been won.
These are the
schools we are building now.
And while the arguments about
the new philosophy of education may not be finished
indeed as a parent rather than an architect, I get into
these arguments myself - architecturally speaking, the
hard-soft school is here:
Advances in the use of audio visual media, the development
of multi activity classes, and progress at
a child's own
rate seem to demand a change in the old hard school.
The
handling of the spaces - which is what architecture is
mostly about - has to be changed.
For development and change
in curriculum, in the way the child works, learns and
progresses, seems to be inseparable from changes in the
design of the school itself.
It must be easier for a teacher
to adopt a more flexible program in a room or
space with
flexibility built in.
That said, I might add that we have advanced architecturally
quite rapidly in the last few years and I am conscious
that the time may have come to re-evaluate
correct, and
improve on some of the changes we have designed into
the
new schools.
What I mean is, that the architect cannot
know whether movable partitions and all the
rest work well
in the teaching situation.
And it is up to the educators
to tell us where and when we have gonewrong; and I would
suggest a field group of educators and architects to
report
this year on our combined progress.
Now, speaking as an architect with some knowledge
of school
design and leaving the field of educational
philosophy
completely, I would like to point out that
you can't possibly
have a completely flexible, completely unordered
space in
30
which educatior is going on.
One has to structure space
for certain functions within a school.
One has to consider
noise, odors and safety factors.
This is so obvious that perhaps it has been missed by
some
of the more radical proponents of flexibility.
The Ontario
Fire Marshal's office, for instance, is concerned that
science rooms and home economics rooms be walled off.
There
are washrooms, gymnasiums, private counselling rooms,
industrial shop and the service areas that have to be
separated from the rest.
Where we can be flexible in the handling of space is in
the resource centre, the kindergarten and the general
classrooms.
Architects can meet the new demands for
flexibility in these areas and produce imaginative plans
that incorporate the educators requirements.
But it is important that the educator assess the impact
of these changes and not merely shift the educational
prob'ems that arise to the architect.
I guess what I
mean is that if some of the new ideas in design and handling
of spaces don't work out in practice for the principal
and his staff, he shouldn't blame the architect.
For
in demanding flexibility, the educators have often been
vague.
Let us have programming developed more specifically.
Neither the educators nor the architects are trying to make
changes in school design purely for changes' sake.
We
are both trying to make education more effective.
And
of course, in the process, both architects and educators
do a certain amount of "learning by doing"
- a concept
which I assume has your wholehearted endorsement.
As we
build schools, we learn how to design and build better schools.
It has to remain a cooperative effort, and I can't emphasize
this enough.
The program requirements have to come from
the educators, and the architects cannot solve
your educational
problems.
One field in which I can perhaps contribute
some knowledge
is the field of costs.
The new flexible schools are more
costly than the old hard schools because carpeting,
for
instance, required for sound control and floor resiliency
can increase square footage costs by approximately $1.00
per square foot over vinyl asbestos tile.
Large open column-free areas increase structural costs
by twenty-five to fifty cents.
Flexible and operable walls vary in cost from $5.00 to
$10.00 a square foot against $1.15 for a painted block wall
or approximately $3,000.00 - $6,000.00 per classroom
versus only $800.00 a classroom.
It is in this field of building costs that the architect
can make a real contribution to the educator's problems -
the educator who has all these wonderful ideas but is
spending the tax-payers money and has to watch his costs.
We can offset these costs for you.
For instance, if you
carpet the floor, we can suggest eliminating the acoustic
tile ceiling.
You don't have to have column-free space to be'flexible
in my opinion.
You can group wardrobes or project counters
around columns.
That is, you can have the columns but
not'the walls - this is less expensive than large
spans.
Flexible walls are really expensive and if your slick
partitioning system requires two strong men and a ninety-eight
pound teacher to open up or close a wall, you defeat the
concept surely, through the inertia of the teacher.
You
can provide open teaching areas in small clusters and
utilize cupboards and movable chalk and tack board to
separate area.
In summary, the new flexible schools do at the moment, result
in approximately a $1.50 per square foot extra to the
tax-payer.
The architect then,by inclination and design, is an
innovator when it comes to the school.
He is interested
in new ideas in education and anxious to design schools
which will make these ideas effective.
But he cannot
tell the educators what a school should be like.
They must
tell him.
Then at that point, he can have some good and
useful ideas about how best and most economically this
educational function can be carried out.
THE COMPUTER AS A TEACHING AID IN THE SCHOOL PROGRAM by
Mr. G. Bonham
The computer, as a teaching aid, can take somany different
forms that one of our problems this morning will be to
keep
track of them all.
However, if we approach the problem
by first describing each requirement and then trying
to
find a solution to meet that requirement, the
most logical
overall solution should emerge.
First I would like to show you the
couraes involving the
computer that are either available right now
or will soon
be available.
From the chart, you will notice that there
is a program available in each of the three
streams:
Business and Commerce on the left, Arts and Science
in
the middle and Science, Technology and Trades
on the right.
Actually, in any of these programs, the computer ismore
of a learning aid than a teaching aid but in either
case,
it is an integral part of the program.
Starting with the Business and Commerce
program which was
the first established, we will approach
course content not
from a philosophical point of view but instead from
the
point of view - where is a computer needed?
For instance,
the Grade 10 program can be taught without using
acomputer but the Grade 11 course cannot.
The course
is called basic programming and the objective
is to
introduce the student to programming and not,
by the way,
to make a programmer out of him.
Therefore, to meet this
objective, access to a computer is absolutely essential.
Similarly, the students must have
access to a computer in
the Computer Science program of the Arts and Science
branch.
Here the emphasis is on problem-solving
that is, a study
of'algorithms.
An algorithm is a step-by-step solution
that must be infallible for all
cases of input.
The
teacher could check an algorithm for infallibility
but he
wouldn't last long.
Therefore, let's give the problem
to a computer because a computer just happens
to be a
very competent "algorithm-checker".
Thus once more, access
to a computer is essential.
31
In the third program which is more embryonic than the other
two and which does not yet have a Department of Education
course of study associated with it, the use of the computer
will be somewhat different.
In this course, the students
will learn about the circuitry of the computer; all about
switches, triggers, logic subsystems and any other electronic
elements utilized in the computer.
To meet this need,
they will require suitable hardware for "hands-on"
experience.
Simple circuits can be "breadboarded" quickly for analysis
of operation.
For the study of more complex circuitry,
however, computers, or computer sections which
are so
constructed as to permit measurement of operating conditions,
would be valuable.
In addition to this "hands-on" experience with the circuitrY,
the students of this program will likely write
some programs,
so in that sense they need the same kind of facility as
do the others.
In summary, then, the type of facility required to support
all three programs is one that will process student
programs;
and there is the extra requirement of
access to circuitry
in the S.T. & T. program.
Now let's look at some of the possible solutions
to meet
these requirements.
You probably noticed that I useu the
words computer facility racher than computer.
The reason
for this is that the facility can take
so many different
forms.
For instance, it could be a computer in the school,
so let's explore that for a moment.
At the present time.
there are at least eleven schools in Ontario that have
computers installed.
There are five manufacturers represented;
they are:
IBM, Honeywell, General Electric, NCR, and
Digital Equipment.
There may be others of which I am unaware
and, if so, I stand corrected.
The machines installed
range in price from approximately $8,000 purchase to
approximately $120,000 and, of course, theta is
a corresponding
variation in computing power.
The important note here is,
however, that the tve4 of computing equipment really
doesn't
matter insofar as the learning situation is concerned.
There is a fairly high transfer rate of knowledge
as one
uses various computers.
Moreover, the stress is either on
concepts or on problem-solving in all the
programs.
The
concepts
in computing are independent of type of machine
and so is prsblem-solving.
Therefore, the only requirement
32
is some sort of hardware and the best hardware will be
that which does the best job on student programs.
Once
the hardware has been decided on, another problem must
be
faced; where to locate it in the school.
Most of the
schools that have computers installed are putting them
in rooms partitioned off from regular classr.7oms.
It is
desirable that access to the classroom portion be maintained
but also access to the outside hall is required
so that
students can come in and use the computer during their
free
time; even when a class that is not using the computer is
going on next door.
Because of this, the partition should
be fairly soundproof.
Also, it is desirable that the teacher
next door keep an eye on proceedings since the machine is
quite an investment.
Therefore, the most popular partition
wall is ore that contains a large percentage ol7 glass.
In
general, this is the type of computer room that is being
built and, as far as I know, is working out
very satisfactorily.
At the present time, the computer room is generally under
the supervision of either the mathematics head
or the
commercial head.
It has worked out this way because these
are the people who 11:.ve been involved with the courses
that I described a moment ago.
It is my hope that two things
will happen that will alter this somewhat.
First, I hope
that computing will be used in almost
every subject although
the present courses with their special emphasis
on computing
will still remain.
For example, a geography class could
use a computer to investigate the effects of border changes
or population shifts.
A biology class could use it to
simulate bacteria growth, and so on.
Secondly, because
of this wider use of the computer in curriculum,
I hope
to see the computer as easy to get at
as, say, the office
duplicating machine.
This machine knows no subject boundaries
and neither should the computer.
Trends in hardware
development lead me to believe that computers willbecome
more and more automatic and much less esoteric.
Hence, the
school of the future, may have a computer
room accessible
by students, staff, principal, and office
staff.
What about the requirements of electronics
students?
Should
they have access to the circuitry of this
general purpose
computer that I have just described?
The answer to this
largely depends on the utilization.
I see no particular
harm in having them check circuitry with
oscilloscopes and
other test instruments but remember that the
computer is
inaccessible for anything else during this period.
Therefore,
if utilization is high, I would suggest that its "down-time"
be kept to a minimum.
Hence, it would be wise to take the
computer sections approach and have various parts of the
computer in the electronics shops.
This also has the
advantage that test equipment doesn't need to be moved
around quite so much.
Let's summarize here by considering this situation to be
the first under consideration; that is, a computer in the
school for processing student programs and parts of computers
available for the electronics students.
There are other types of access to a computer: for example,
regional centres.
There is a rule of thumb for computers
that says:
if you double the price, the computing power
goes up by a factor of four.
Thus a large school system
may find it more suitable, particularly financially, to
have a large central computer and bring student programs,
teacher programs and so on to the computer.
This is being
done already in some of the Metropolitan Toronto boards
which have courier services established for picking up
and delivering programs.
If this is done, the computer
facility in the school becomes simply a place to leave and
pick up programs.
The only factors here are logistic in
nature.
A variation of this large central computer approach is
to have computer terminals located in the school.
Here
there are variations an well but most terminals will be
of the type that transmit over voice-grade telephone cables.
If the terminal is portable, and it likely would be, it
may be desiranle to put it on a cart and take it to the
geography room for the geography class and the mathematics
room for the math class and so on.
This would require
telephone jacks to be installed in various rooms, but
how do you predict which rooms?
This, I would say, is
impossible to guess at but perhaps in planning construction
it may be possible to make it quite easy to install
telephone jacks in any room.
I don't know the expense
involved here - it may be too high to do but then again,
it may not.
Still other computer facilities are mail-in services to
anumber of different agencies such as universities, commercial
firms, colleges of applied arts and technology and teacher-
training institutions.
This type of facility is essentially
the same as the courier set-up and the factors are all
logistic.
Choosing the best facility is a real problem.
It wouldn't
be so bad if manufacturers would declare a moratorium on
new products so that we could decide what is best from all
the presently-offered products:
but this is hardly likely
so we have to remain as flexible as possible.
If I had
to decide right now, I would do so by considering two
trends that are rather important.
First, technology is
advancing quickly in the communications area, making
communications cheaper and better.
Secondly, technology
is advancing quickly in computer development.
Computers
are getting faster, cheaper, smaller and easier to use.
If these trends continue, and I fully expect they will,
then I would favour the installation of a small computer
in the school that has the facility of being a remote
terminal as well.
By this I mean that it should have the
capability of doing all the "in-house" student programs
but in addition it should have the capability of being
hooked up by a telephone network to a large remote oomputer.
This remote computer will be used for centralized collection
of data, for solving very large student problems, and for
storing data to be used in information retrieval by the
schools.
The computer at the school should be accessible by all
persons that I described earlier.
Just where to put it
in the school, I don't honestly know.
Perhaps the best
location would be close to the school office for ease of
use by office personnel and as remote as possible to
conventional classrooms so that students can go in and out
without disturbing other classes.
This is what I personally would choose at the moment.
But
I don't know what developments are just around the corner
and I may change my opinion tomorrow; but, just
as I have
made a decision as to what I think is best at the moment,
so will you likely have to make a decision; and all you
can do is to assess the factors as you see fit and try
to remain as flexible as possible.
One of the areas that I haven't even touched iscomputer-
assisted instruction but I think CAI is much more remote
than using the computer in the ways I have just described. 33
Also, it seems to me that the planning of facilities for
independent-study carrels parallels the planning for CAI.
Perhaps part of the study carrel will be a computer terminal
to be used for CAI.
If so then adequate cable facilities
will be required, probably an infinite raceway in the floor.
The cable connections might be coaxial cable or they might
be voice-grade telephone lines.
I believe that this depends
on where the computer is located.
However, CAI is still
fairly remote for us and, while I agree that planning for
it is important, I wish to stress this morning a shorter
range of planning and that is, the provision of a computing
facility for our children.
34
PHYSICAL AND HEALTH EDUCATION FACILITIES IN SCHOOLS
by Mr. J.M. Metcalf
PART A
It is certainly not my intention to consider with the group
any of the technical aspects of architecture or of building
construction.
What I do feel some competence in, and what
I would like to discuss with you this morning, is the
question of the function and the use of physical and health
education facilities in schools, and those aspects of
design and construction which may make *his function either
more, or else less, effective.
Certainly, my involvement
with these kinds of facilities - as a student, an athlete,
a teacher, a coach, a department head, a director of
athletics, an inspector and a program consultant - has
always been from this point of view of function.
In order to appreciate function it is necessary for one to
be aware of at least the basic principles and programs
in school physical and health education today.
Perhaps
more than any other subject field, physical and health
education faces the danger of being sterec:yped.
This danger
of being 'cast in a mold' derives from the old "PT" programs
which consisted primarily of Danish calisthenics, military
drill, and a "play the game" situation in which ten people
played while the rest awaited their turn.
Activity programs
were generally based upon the "big foLe of football,
basketball, volleyball and track and field, with'a little
gymnastics sometimes thrown in for the open house display,
and a little softball in the late spring.
Health instruction often consisted of a watered down
course
in anatomy and hygiene, with a lecture presentation, and
with copious note-taking on the part of the students
so
as to be able to regurgitate the information on a test or
examination at some later date.
The setting for this type
of health instruction was not particularly important.
Today's physical education programs include approximately
twenty eight activities in which the students may be involved
during their school experience in the subject.
The immediate
aims of the program are the development of a high level of
total, personal physical fitness, and the development of
each student's kinesthetic abilities - his perfection of
the art of movement and the efficient utilization of the
body in movement - through the medium of athletics and
physical activities.
There are also extremely important
long range objectives in the program - particularly in
terms of mental and of psycho-social development.
In order to accomplish these aims and objectives the four key
words are "movement" - "involvement" - "activity" and
"individualization".
The subject matter of physical
education is movement - and movement requires space.
It
is essential that all students in the class be actively
involved for the greatest possible amount of time.
Physical
education programs today are structured to achieve maximum
activity by all class members, at a level suited to their
individual abilities, aptitudes and interests.
In general,
the effectiveness of a physical education lesson is in
direct proportion to the amount of equipment used, and
is in inverse proportion to the size of the individual groups
engaged in the activity.
The implications in this concept,
with regards to the need for space and for "good" facilities,
are most obvious.
Health education today focuses upon student involvement and
student discovery.
It utilizes such activities as large
and small group discussions, discovery situations, experiments
demonstrations, role playing, debates, laboratory situations
and student presentations.
Enrichment through the use of
aids, models, charts, audio-visual equipment etc.
is most
desirable.
A specific environment for this type of
educational experience is practically essential.
PARTS
With rP-ards to specific facilities for physical and health
education - both gymnasia and ancillary areas - I have listed
many of the desirable features in point form in the printed
version of my talk, and on the overheads which I will be
using in a very few moments.
I would like to cover the
specifics of the individual areas rather quickly, with
comment only upon those situations where problems often
tend to occur.
Hopefully you will then raise, in the
discussions which are to follow, any points which may
be of particular interest or concern to you.
While my focus in this talk will be primarily upon facilities
for secondary schools, many, indeed most of the general
principles - particularly with regards to gymnasia, change
rooms and showers - will apply equally to the facilities
in K-8 schools.
Although I will, of necessity, be
speaking about the "ideal" situation, I realize only too
well that there are many variables - economic, school site
previously existing facilities and so on - which must enter
into the deliberations of those involved in planning and
constructing new facilities.
And of these, without any
doubt, the economic variable has to rank number one.
In considering the total physical education facility the
initial focus, from the point of view of function, should
be - not upon the gymnasium - but upon the change room.
(PROJECTUAL)
There must, of course, be access from the
change room into the school building.
There should also
be direct access doors or openings into the gymnasium,
the instructor's office, the drying room, the toilets
and the outdoor facilities.
Access to the showers should
be only through the drying room.
The instructor's office
should also have direct access into the gymnasium and into
the school corridor.
Ideally, six kinds of storage should
be provided as shown on the overhead.
(Four - heavy
equipment, supplies in daily use, chair, and community-opening
directly into the gymnasium; one - outdoor storage- opening
only into the outdoor facilities; and one - dead storage
-located in the general area.)
Within the general physical
and health education complex, but not necessarily opening
into any of the above facilities, should be the health
education room, the dead storage - team room complex,
and any other ancillary areas.
On the projectual, red lines indicate that there should
be doors - green lines indicate that there should be openings
to separate areas, but no doors.
(Openings only, between
change room and drying room, drying room and showers, and
change room and toilets.)
However, each area should be
separate and self-contained.
(SERIES OF PROJECTUALS)
35
GYMNASIUM NO. 1
Capacity:
Number of periods per class
School Capacity
xper week or cycle
Formula:
Average Class Size
Total Periods per Week or Cycle
e.g.
1500
X2-
3.57
30
42
..
4 teaching stations are required
1500
130
42
1.19
2 health education rooms are required
GYMNASIUM NO. 2
Location:
- Separate, so that noise will not interfere with
other classrooms.
- Capability for closing off the complex from the
rest of the school, particularly if community use,
and the concept of the "lighted schoolhouse" is
being considered.
- Need for easy access to outdoor facilities.
36
GYMNASIUM NO. 3:
Size
High Schools and Collegiates:
- Single Gymnasium:
80' x 50'
- Double Gymnasium:
80' x 100'
- Minimum Height:
22' clear.
Senior Public, and Junior High Schools:
- Single Gymnasium:
70' x 45'
- Double Gymnasium:
70' x 90'
- Minimum Height:
20' clear
K - 6 and K - 8 Schools:
- All Purpose Room:
60' x 50'
- Double All Purpose Room:
60' x 100'
- Minimum Height:
18' clear
GYMNASIUM NO. 4:
Floor
- Hardwood preferable to parquet or tile
- Built-up is superior to flush laid
- Proper location of floor sockets and plates is most
important.
Socket other than the "sleeve" type
are generally not effective.
- Sockets to support the horizontal bar should not be
centred on the floor, but should be to one side, and
preferably towards one corner.
- Care should be taken to ensure that all court and
floor markings conform to the latest rules and
regulations as laid down in the
current official hand-
book of the sport concerned.
GYMNASIUM NO.
5:
Walls
- For at least the first 16' from the floor and
preferably for its entire surface, the wall must
be clear, and as smooth as possible.
There should
be no projections, decorative brick work, acoustic
treatment, mid-wall heating apparatus, glazing
etc.
Otherwise all rebounding, which normally
constitutes a considerable amount of gymnasium
activity, is Impossible.
- There should be a washable, protective coating for
the first 12 feet.
- All external corners should be rounded.
- All basketball backstops should be swing -up or
swing -away in order to make the total floor
area -
particularly cross court - available for other activities.
- No drinking fountains in the gymnasium.
GYMNASIUM NO. 5:
Roof Structure,
- Recommended heights must be clear heights.
- Pre-cast construction magnifies the problem of
acoustics.
Reverberation time should not exceed
1.6 seconds.
- Attachments for ropes, rings, etc. in pre-cast
must be placed carefully in order to avoid
problems.
- A suspended flush ceiling is very susceptible to damage.
_ Ceiling design which traps balls, badminton birds etc.,
should be avoided.
GYMNASIUM NO. 7:
Exits and Entrances
- There should flush floors, with no sills, at all
entrances to the gymnasium.
- Traffic across the gymnasium in street shoes must be
avoided.
- Doors should be flush with inside walls.
Handles
should recess.
- Doors should open outwards.
- Doors should be sufficiently sturdy to accommodate
up to 800 "pupil passages" per day.
- Ventilation panels at the bottom of change room
doors should be avoided.
GYMNASIUM NO. 8:
Lighting
- Large glazed areas have several disadvantages.
i)
Glare. Often covered with drapes which
are
never opened.
ii)
Breakage
iii)
Heat loss, or gain, and condensation.
iv)
Limit use of walls as instructional
aids.
v)
Artificial lighting is still required.
vi)
They are not needed for ventilation.
- The relationship between the colour scheme and the
quality of light should be carefully
considered.
- Minimum lighting should be 30 foot candles taken
4 feet above the floor.
- Light should be uniform.
Dark and light bands
should be avoided.
37
GYMNASIUM NO. 9:
Ventilation and Heating
- Should be controls for gymnasium only.
- System should be quick responding.
Hot water is
not efficient.
- Relative humidity should be maintained at a proper
level.
- Noise from air movement or from mechanical apparatus
often creates problems.
- There should be a minimum of 6 air changes per hour.
At least 50% should be fresh, outside air.
The
remainder could be re-circulated.
- Temperature should be 60-65 degrees Fahrenheit at
4 feet above floor level.
GYMNASIUM NO. 10:
Folding Door
- Should be solid and capable of use for rebounding
activities.
- Complete separation between the two gymnasia is
essential.
- The hanging type of door is preferable.
Floor
track is not recommended.
- Allowance must be made for building settling.
- A small connecting door in the folding door is essential.
- When opened, the door should be completely recessed.
- If possible the storage for the open door should not
infringe upon equipment storage areas.
- The controls for the door should be at the closing
end of the door.
38
GYMNASIUM NO. 11:
Electrical Outlets and Public Address
- A clock outlet should be provided in each teaching
area of the facility.
- There should be a reasonable number of wall mounted
convenience outlets in strategic locations.
- Wiring for an electric scoreboard should be installed
at the time of construction, even if no board is
planned for the immediate future.
- There should be a unit of the school's public address
system in each teaching area of the facility.
- Lights should be controlled by more than just one
master switch.
CHANGE ROOMS NO. 1:
General
- These should be 550 square feet.
(900 square feet for
boys if a 350 square foot team room is not provided).
- Minimum of 9' ceiling height.
- Floors impervious and non-slip.
- Minimum lighting of 15 foot candles at 4 feet
above the floor.
- Drains in the floor, including one close to the drying
room entrance, are essential.
Floors should be
properly sloped to the drains.
- Should be a hot water hose connection for cleaning.
Controls should prevent student operation.
- Sharp corners and projections must be avoided.
- Screens and baffles as visual barriers at entrances
must be provided if required.
- Good ventilation is absolutely essential.
The minimum
is 6 air changes per hour with at least 50% being
fresh outside air.
- Temperature should be 78-80 degrees taken 5'
above the
CHANGE ROOMS NO. 2:
Organization
floor.
- K - 8 Schools:
400 square feet.
- Lockers and lockerettes are not recommended.
- The number of change rooms required in the
total facility
is one more than the largest
odd number of teaching stations.
- Fixed benches, 16" wide and 18" high should be
provided at all available wall space.
They should
be attached to the wall rather than to the floor.
- 5'-10" above the floor a 12" shelf should be
provided above all benches.
- Hooks should be installed on the wall just below
the shelf, at 15" intervals.
Hooks with dual short
projections should be used.
Large, traditional
style coat hangers are most ineffective.
- Mirrors should be conveniently located on the walls.
- A clock and school PA loudspeaker should both be provided.
- There should be a drinking fcantain in the dressing room.
- A "valuables box" should be provided - either in
this room or in the door between it and the instructor's
office.
DRYING ROOM:
- Only way into showers.
- 150 square feet.
SI:ape as nearly square
as possible.
Ceiling a minimum of 9'.
- No furnishings except for short, rust resistant
hooks
for hanging towels at 5' from
the floor.
(Towel rails
are not desirable).
- There should be a 4" curb between the dressing
room
and the drying room.
- Light fixtures must be moisture proof.
- Good ventilation is essential.
39
SHOWER ROOMS NO. 1:
General
- Accessible only through drying rooms.
- 225 square feet.
Ceiling a minimum of 9'.
- As nearly square as possible.
(15' x 15').
- Drainage.
One or two conventional drains in the
centre of the floor leads to problems.
The room
requires perimeter drainage, or a large, slatted
drain between the dressing and drying rooms.
Floors
must be properly sloped.
- There should be a master control in a locked, recessed
panel in the dressing room.
It should not be in
the instructor's office.
Individual controls are
not necessary, although one or two may be desirable.
- Minimum of 6 air changes.
At least 50% fresh air.
- Moisture proof light fixtures are essential.
- Temperature 75-80 degrees at 5' above the floor.
- Lighting:
10-15 foot candles at 4' above the floor.
- Separate exhausting is most desirable.
- Soap holders and dispensers, if desired, should
be recessed.
SHOWER ROOMS NO. 2:
Boys and Girls
Boys:- 10 to 12 shower heads
- 6'6" from tht. floor
- Individual heads around the walls are more
efficient than the pedestal, column or pillar
type of shower.
Girls: - The need is for individual cubicles with an
attached change area.
- Six such are recommended.
- If the bulk of the showers are open, then at least
40
two cubicles must still be provided.
- Shower heads should be
56" from the floor.
- Hair dryers, if provided,
should be in the
dressing room.
TOILETS: - It shouldbe a separate room serving only the
dressing
room.
It should not serve as a general
school
washroom.
Access only through the dressing room.
- No mirrors in
this room.
- No drinking
fountain in this room.
- Boys:
2 toilets, 4 urinals, 2 washbasins.
- Girls:
4 toilets, .2 washbasins.
- Separateventilation desirable.
If not, exhaust must
be from the offices and change rooms,
to the showers,
to the toilets and then out.
INSTRUCTOR'S OFFICES:
- 225 square
feet.
in addition to Physical Education
Staff this room is used by other
staff coaches,
academic supervisors, and officials.
- Minimum height
of 9'.
- Temperature
68-75 degrees.
- 25-30 foot
candles at desk level.
- Washbasin,
mirror, medicine cabinet, toilet and
shower in a separate room or roomettewithin the office.
Shower available for independent use.
- Provision to ensure
that water from the shower does
not escape onto the office floor.
- Locker
accommodation for at least 6 persons.
- Vision panels, no more
than 24" by 24" with the
sill 4' above the floor, should be provided
between
the office and the gymnasium, arid theoffice and
the change room.
One way glass should not be used.
- Good ventilation
is essential.
- Normal unit of
school PA should be installed.
- At least 2 duplex
electrical outlets.
- There shouldbe one office for the male staff, and
a second office for the
female staff.
In open
concept schools, or schools which
plan to operate
with individual timetables and/or
electives, a
common planning area .between
the two offices might
be considered.
STORAGE AREAS NO. 1:
Requirements
a)
Heavy gymnastic apparatus
b)
Supplies in daily use
c)
Dead storage
d)
Outside storage
e)
Chair storage
f)
Community group storage.
STORAGE AREAS NO. 2:
Heavy gymnastic apparatus
- Double gymnasium:
700 square feet of usable floor space
with openings into each half of the
gymnasium.
- Single gymnasium:
450 square feet.
- Floor level withgymnasium floor.
- Heavy, overhead roll -uptype of door, at least 6' wide
by 8' high.
- Ceiling at least
8' high.
- Lighting recessedand protected.
STORAGE AREAS NO. 3:
Supplies in daily use.
- 120 square feet of
floor space
- One for eachhalf of double gymnasium
- Directly accessible
to gymnasium
- Shelving and
cupboards on all walls.
41
STORAGE AREAS NO. 4:
Dead Storage
TEAM ROOM:
- 225 square feet of floor space
- For storage of out-of-season uniforms, supplies,
and equipment, and maintenance of
same.
- Good ventilation is essential.
- Shelving and cupboards required on all walls.
- Should be provided with a Dutch-door.
STORAGE AREAS NO.
5:
Outside storage
- 350 square feet.
- Most desirable for large scale, after-school activities
- Only way to store and dry uniforms during the season.
- Leaves gymnasium area free for intra-mural activities.
- Showers and drying room would, ideally, be included.
VISITORS' DRESSING ROOM:
- A most desirable special service area, particularly
- Should open directly onto playing field.
No
in a large school.
other access.
- Sufficient in size to accommodate football blocking
sled, blocking dummies, field markers,
jump standards,
shot and discus circles, shot and disci,
hurdles,
vaulting poles, field markers, lime
etc.
STORAGE AREAS NO. 6:
Chair Storage
- If the gymnasium is to be used for assembly and
auditorium purposes, additional storage
space to
accommodate the maximum number of chairs
required
should be provided.
STORAGE AREAS NO. 7:
Community group storage
42
- 350 to 400 square feet with 'its' own shower and
toilet facilities.
ACTIVITY ROOMS:
- The provision of activity rooms in what might other-
wise be wasted on poorly used space- e.g. over the
gymnasium service areas
- is most desirable.
STAGES: - Only if absolutely necessary.
The advantages of
cafetoriums over gymnatoriums should be considered.
- The area of the stage should not reduce the clear
- Separate storage should be provided, large enough
to accommodate the equipment of all
community groups
who will use the facility.
dimensions set forth for physical education
purposes.
- The stage should not protrude ;nto the gymnasium proper.
- A net curtain should be provided to keep balls etc.
from going onto the stage area.
SWIMMING POOLS:
- Swimming pools must conform to the "Regulation made
under The Public Health Act respecting Public
Swimming Pools".
- It is expensive.
Close consultation with all possible
user-groups in the community should develop to
ensure maximum use.
- Plans and specifications for a pool and its ancillary
areas must be submitted to the Department of Health.
I would now like to comment very briefly upon two remaining
considerations.
First, a specifically designed and
designated health education classroom within the total
physical and health education complex is practically essential
if the meaningful experiences in health education, which
I mentioned at the beginning of my talk, are to be provided
for the pupils in the particular school.
(PROJECTUAL AND COMMENT)
My final remarks have to do with an extra benefit which
may lerive from thoughtful school planning.
If the facility
is GO designed, a blank, smooth outside gymnasium wall -
more than 100' in length and more than 22' high - can
contribute towards an excellent outdoor area.
With an
asphalt area extending out from the base of the wall
from 50 to 80 feet, an outstanding multi-purpose outdoor
facility can be provided.
The wall serves for rebounding
activities, for the attachment of outdoor baskets and
other equipment, anc. as a backstop at one end of the two
or three tennis courts which could be provided.
These then are the outstanding specifics, once again from
the point of view of function, for the various areas
which constitute the physical and health education complex.
I would now like to presume upon just a few more moments
of your tike in order to illustrate, by means of some
35 sun slides, some of the points upon which I ha2 been
commenting,
(35 MM SLIDES AND COMMENTS)
I would like to thank Mr. Orlowski and the School Planning
and Building Research Section of the Department of Educ_ation
for the opportunity to speak with you this morning.
I
will certainly be available for the remainder of the seminar
for anyone who might wish to discuss any aspect of physical
education facilities in schools.
I would also like to
add that the Program Consultants for Physical and Health
Education in the ten Regional Offices of the Department
of Education - myself in Region 9 in Kingston, and others
in the other nine Regions - are most ready, and would
indeed welcome the opportunity to consult with you at any
time regarding proposed new facilities for Physical and
Health Education.
Thank you.
43
PHYSICAL EDUCATION FACILCTIES by Mr. H.H. Roberts
A glance at the program for this Workshop clearly indicates
that in general many people of diverse interests and
capabilities have been brought together in an environment
conducive to an exchange of ideas and opinion concerning
the relationship between education and architecture.
In
each of the panzl disucssions and group meetings, speakers
have been selected to represent the people who use schools
and those who build them.
I assumed, therefore, that
for the purposes of this group meeting Mr. Metcalf as
Program Consultant would address himself to the subject
of Physical Education as a phase of total education;
that he would deal in some detail with the needs of
children and youth, the programs designed to meet these
needs both now and in the future.
I would then be expected
to talk about the facilities to house physical education
activities and perhaps comment on such things as safety
precautions, appropriate materials, structures, and services.
Having designed a number of gymnasiums and general
purpose rooms, some good, some bad and some very bad, I
feel qualified to speak about these subjects but dn not
intend to do so because I believe there are perhaps more
important things to discuss before we start talking about
the hardware.
And lest you think I am avoiding the subject
this may be as good a time as any to say that on March 11th
I had the opportunity of talking to Mr. Andersen and
Dr. Aboul-Khair of School Planning and Building Research
and had the privilege of being shown the draft copy of
a new and, in my opinion, a most exhaustive treatise on
General Purpose and Physical Education Facilities.
Virtually every aspect of the subject, from site planning
to the height of a bench in a change room is dealt with
completely and competently.
Mr. Andersen stated that he
was hopeful of having the manual ready for distribution
by the time this Workshop took place.
44
This is the third EA Torkshop which I have attended
motivated by an earnest desire to learn from the "Educator"
the facts about the learning program so that I as an
architect could design a better school.
Imagine my initial
dismay then when I discovered that of all people the leaders
of the teaching profession had no definitive answers to
give me.
I was at once discouraged and angry.
Smarting
from accusations of building soap-box schools I proclaimed
that if they can't tell me what they want how can I be
expected to design a building to suit the educational process
for the next fifty years.
Fortunately anger sometimes
provokes thought and I gradually came to understand that
if the "Educator" could give me a definitive answer education
is necessarily static and we are dead.
It is my belief that an architect or for that matter anyone
other idividual, can no longer he delegated to produce the
perfect plan.
Such an assumption implies a mastery of the
massive amount of knowledge now available in such diverse
fields as sociology, environmental conditions, urban
and regional planning, economics, automation, recreation,
psychology, health and medicine.
It is clear to me that
the architect can not be a r!rson characterized as one who
draws pretty pictures, makes a lot of money, and whose total
exercise consists of bending his elbow.
He must become a member of a team whose collective knowledge
is tuned to today's wave length.
Until and unless this
happens on a wider scale it is difficult to foresee better
school buildings and physical education facilities.
The "Hall-Dennis" report has this to say about Health and
Physical Education.
"Since good mental and physical health are essential
in achieving maximum benefit from the learning experience,
this area of the curriculum deserves special consideration.
In this connection significant trends in our society have
emerged to demand the attention of those who provide learning
experiences for young people.
New forms of mental and
physical stress, changing codes of ethics, and new advances
of leisure time have placed new responsibilities on the school.
In the face of these trends, from drug consumption to spectator
sports, from sexual ethics to physical development, the
curriculum must demonstrate new ways of helping young people
to meet the problems of reaching for emotional end physical
maturity.
It is not enough to provide the traditional series
of "health lessons" in the name of health education, or to
provide regular periods devoted to popular team sports.
Programs must provide, not the prescription of conventional
courses, but learning experiences which will help young
people in searching for solutions to the immediate problems
that all young people face as they develop.
For a boy
of poor physical prowess, a sense of adequacy is just as
vital as skill in games, perhaps more so.
Likewise,
freedom to ask questions and to get accurate answers
regarding seemingly calamitous physical development is of
greater consequence to a young girl than ability to name
the parts of the body.
A good school will be sensitive to the emotional
and physical needs cf its pupils and will respond to these
by developing programs that reflect this sensitivity."
If such an enlightened program is to be instituted or
augmented and the proper facilities provided it seems to
me that we must know who these children are and where they
are.
The Minister's report for 1967 provides the latest
available statistics and in themselves have many things
to say.
In 1967 the total enrolment in our elementary and secondary
schools was 1,868,788 distributed as follows:
Elementary
Enrolment
1,405,052
Increase over previous year
40,181
Secondary Schools
Enrolment
463,736
Increase over previous year
27,710
Pupils were further distributed as follows:
Elementary: Grades 1 to 6
Gradea 7 & 8
SecondaryL Grade 9
Grades 10 to 13
- 55%
- 15%
70%
- 7.5%
-22.9%
030%,
The significance of these statistics is fundamentally
important.
The preponderance of elementary school children
is startling enough without asking where, when and why one
million children and youths went.
If the proposition that 50% of the total pupil enrolment
is mentally incapable of proceeding beyond the Grade 10
level it may not be unrealistic to assume that something
like 1,000,000 students have gone two years after leaving
the elementary school.
The magnitude of the responsibility which this situation
imposes upon the secondary school is difficult to comprehend,
but in itself indicates the even greater responsibility
of the elementary schools having in mind that all children
will be taught by them while the secondary school, at
the present time deals with only 25% of the total.
Unless we are prepared to accept a nation of spectators
and widow makers unprepared for fifty-five or sixty years
of automated leisure and tension we should then perhaps
begin by examining our thinking and facilities at the
elementary level.
Of the some 4,750 elementary schools in Ontario about 1,650
schools consist of one to six rooms; some 2,000 schools
of seven to fifteen rooms; 1,100 of fifteen to over thirty
rooms.
It is quite probable that all of the 1,100 large
schools, most of the 2,000 medium schools and some of the
1,650 small schools now have separate physical education
facilities.
It seems unreasonable to think that once built,
existing facilities will or can be changed.
It is fair to
assume,however, that in time, new County Boards will
consolidate smaller schools and it is in this direction and
especially in the construction of new schools either urban
or rural that we should look for the improvements of
facilities.
Most general purpose rooms built during the last ten years
or more conform to stipulated areas and ceiling heights
in order to qualify for grants: the result being that the
vast majority of schools possess a single room varying in
size from 1,500 to 3,000 square feet more than likely with
a stage added and most with a ceiling height of 16'-0"
clear of obstruction.
These figures in themselves invite
45
the following questions:
1.
Why is it that one room should be 1,500 square
feet and another 3,000 square feet if the
group of children to be taught is twenty five
to forty in each case?
2.
Why must the ceiling height be 16'-0" clear?
The answers, of course, you know.
In the first case the
room is sized to accommodate the total student body and
the second because the `eight is necessary for basketball
and volleyball.
At this point assume three things:
1.
That because of electronic communication it is not
necessary or even desirable to assemble the student
body in one room.
2.
That either because of Item 1, a fixed stage is
unnecessary or can be replaced by a portable stage
in the round or a folding rectangular platform.
3.
That basketball and volleyball are banned, if not
altogether then at least to the extent thit they
cannot be played outside when and if weather permits.
And here again I quote from the Hall-Dennis report.
"Recognition of recreational pursuits and physical
development should emphasize the aesthetic, social and
physical rewards of such experience rather than team
engagement and spectator participation".
Should these assumptions be accepted the results can be
startling.
To illustrate I have the example of an addition_
now under construction and consisting of a general purpose
room, 2,000 square feet in area with a stage 14'-10" deep
by 32'-6" wide.
The contract price for this structure is
$69,354.00.
If this amount is related to a structure having no fixed
stage and a ceiling height of 10'-0" I have calculated
that it is possible to construct a clear functional floor
area of 3,680 square feet at the same cost.
If 320 square
feet is allocated to storage a net functional floor area
46
of 3,360 square feet is possible.
Please keep this area
in mind.
I will return to it.
While only a person much more qualified than I can define
the character and infinite faucets of children from Grades
one to eight, I venture to say that there is a blurred
but noticeable division between children in Grades one
to four and those in Grades five to eight.
In their paper dealing with Primary Grades Messrs.
E.B. Davidge and L.B. Smith say that Primary children
"are wriggly, peppy, eager, and questioning.
They love to run, jump, skip, dance, hop, climb, throw,
catch, slide, fall down, and get up.
They have a vivid
imagination, and can pretend to be anything or anybody.
They are individuals, not interested in being on a team
or waiting for turns, but want to be active themselves.
At this age, the heart and lungs are smallest in
proportion to body size.
This means that vigorous activity
is needed for muscular development and for increasing
endurance, but that frequent rests are necessary, as the
children tire easily.
They need activities where they can climb, jump,
pull and stretch.
Hanging ropes, tumbling mats, and balance
benches are three of the most useful types of apparatus".
Agility apparatus is one of the best pieces of
equipment for use from kindergarten to grade four.
It
offers a great many opportunities for the children to
climb, jump, pull, twist and stretch.
It also gives the
children the opportunity of making up their own pattern
of movements, so that they are conscious not only of having
fun, but of how they are using their bodies.
I suggest that one half the new found area of 3,360 be
allocated to these children and because they do what they
do and then must rest I would perhaps cover a total of
1,680 square feet and the adjacent walls to a height of
6' -0" with fire-resistant carpet or other resilient material.
I would install unbreakable windows.
A movable partition coulu divide the primary area from
the remaining 1,680 square feet allocated to the upper
grades.
To add flexibility an additional movable partition could
divide the pirmary area :nto two smaller areas for
diversified use as required
While the proposition I have proposed may be small,
unsophisticated, good or bad, it does illustrate that even
a simple change involves many people: such people as the
educator, health and recreation experts, the School Plant
Approval Branch, Grants Department, the architect,
manufacturers and others
I hope it will suggest that
we should forget where we have been and look to where we
are going.
The hardware will follow.
.1
MUSIC FACILITIES IN SCHOOLS by Mr. J.A. Coles
The more I investigate this question of music facilities,
through reading, through talking with colleagues, through
my visits to schools, the more one basic point of agreement
comes to the fore, and that is that before there can be
effective planning in design, construction, etc., there
must be in the words of the Music Educators National Conference
Committee on Music Building, Rooms and Equipment "a general
consensus as to the basic philosophy underlying the
educational program in the community and the nature and
extent of the curriculum that arises from that philosophy.
There can be no single solution or set of solutions that
will prove ideal in every situation.
A physical plant
will be successful in meeting the needs of a given school
only when it is designed in terms of the particular
educational philosophy of the community and when it provides
sufficient flexibility to accommodate reasonable modifications
in th.t philosophy.
With which in mind, the necessity
for a strong, balanced music program must be demonstrated
logically and convincingly by the music educator".
Well then, how does one demonstrate this necessity?
Why
Music?
Why in the school curriculum?
An obvious but
rather superficial answer is that if music were not in the
school curriculum it would be about the only place in
present day life where it was not to be found.
Movies,
radio, T.V. create an environment in which music is an
omnipresent reality.
It cannot be ignored or evaded without
retreating completely from modern life and it is interesting
to notice attempts being made to at least regulate it in
public places.
The Toronto subway ads which say:
"If
you must play your radio, please use your ear phones.
But
it is not simply the fact of its omnipresence which creates
for music a unique place in the school curriculum.
In the
words of the Honourable William G. Davis, Minister
Education fot Ontario,
" music has a special role in the
47
educational process, for it can communicate directly to
the individual without explanation or exploration; it can
transmit and stimulate ideas and emotions; and it is a
language common to people of all cultures.
It is a
fundamental component therefore, in the school experience
of children".
Or as expressed in "The Tanglewood Declaration",
a statement which arose out of a symposium of philosophers,
educators, scientists, labor leaders, philanthropists,
social scientists, theologians, industrialists, representatives
of government and foundations, music educators, and other
musicians who gathered together in 1967 to examine the
theme, "Music in American Society":
"We believe that
education must have as major goals the art of living, the
building of personal identity, and nurturing creativity.
Since the study of music can contribute much to these ends,
we now call for music to be placed in the core of the school
curriculum".
Which indicates that we've come a long way from the "frill"
concept of music in the schools.
As a matter of fact,
looking at the matter historically, we came
a long way to
the frill concept--or perhaps we should simply express it
as a momentary aberration along the way.
Certainly the
idea of music as core curriculum is anything but the
invention of modern day educators; it is ancient and time-
honoured, dating from the civilization of the Greeks.
Looking at our present situation in Ontario schools we find
music to be a compulsory subject in elementary school and
an option in secondary school. Vocal music is the basis
of the program'in elementary schools as it was in secondary
schools up to the post-war years, when instrumental music
began to be introduced as an intra-curricular subject.
Increasingly also, instrumental music is being introduced
into elementary school programs.
I think in the course of the development of school music
programs, ..usic has been taught just about everywhere in
school.
One of the first schools in Ontario to introduce
instrumental music into the timetable was North Toronto
Collegiate and I believe the original instrumental music
room was an only somewhat renovated section of the boiler
room.
My friend and fellow Program Consultant Leonard
Dunelyk who is with me here this morning will recall this
well since he taught at North Toronto Collegiate in these
48
early days.
Music has also been taught in lunch rooms,
gymnasiums, auditoriums, hallways, and washrooms.
Washrooms,
incidentally, have marvellously interesting acoustics for
making music.
They provide one of the surest ways I know
to make your barbershop quartet sound like the Don Cossack
Chorus.
Today we have some very good music rooms throughout the
province.
We have also unfortunately, some rooms which
although quite splendid from the visual standpoint, are
not very good places in which to teach music because
certain fundamental practical considerations were not taken
into account when they were built.
Which points to the fact that the music educator should be
given an important voice
the designing of music facilities.
It is particularly Pssenrial that he be consulted early
in the planning stages and that his opinions be sought
periodically thereafter.
The board of education has an
obligation to consider very seriously the suggestions that
he contributes as has the architect.
It is, of course, necessary to add that it is equally
important that the music educator be aware of the problems
of the architect and administrator.
The teacher should
not hesitate to ask for the equipment and facilities that
he needs, but he must be realistic in his requests and
able to justify them.
And he must understand that the
board of education, which is subject to pressures from
many sources, must reconcile the divergent interests of
various parties, including the taxpayer.
At this point I should perhaps make it perfectly clear
that I speak only as a music teacher.
I claim no particular
insight into or expertise with regard to matters such
as
d*sign, construction, or acoustical properties.
My approach
to these questions stems from my reading, my own practical
experience as a music teacher, and my observations of
others at work in music classrooms.
With which in mind I find it most helpful
to refer to three
checklists provided by the previously quoted Music Educators
Committee on Music Buildings, Rooms and Equipment.
Here
are those checklists for your consideration:
CHECKLIST FOR TF.;.; DIRECTOR OF MUSIC
(or Other Music Person Involved in Planning a Music Facility)
1.
Have you and the teachers involved in the new building
developed a philosophy of music education?
2.
Does this philosophy reflect the newest ideas in music
education so that you will be building for the future?
3.
Do those who will carry on the instruction fully under-
stand their roles in the program of music education?
4.
Have these teachers been given the opportunity to request
facilities that would make it possible for them to do
their best teaching?
5.
Have you made the architect fully familiar with the type
of program you want to carry on in the new building?
6.
Have you given the architect your best estimates of the
numbers of people inv,'lved in each phase of the music
program?
7.
Have you indicated to the architect any special requirements
in acoustics, lighting, location, heating, humidity control,
etc., that are necessary to your program?
8.
:lave you worked with principal to determine how the music
activities will be scheduled in the new building?
9.
Have you determined the equipment which will be needed to
make the new facility functional?
CHECKLIST FOR THE ADMINISTRATOR
1.
Have you developed a general philosophy of education for
your school?
2.
Does your music staff understand this philosophy and
their place in the overall program?
3.
Have you determined the type of schedule the new school
will follow and made certain that the music staff under-
stands its implications for the music program?
4.
Have you helped the music staff estimate the enrolments
in the various activities planned in the music program?
5.
Have you projected these enrolments for at least a
five year period in order to build for the future?
6.
Have you and the music staff considered the implications
of community involvement in music activities?
CHECKLIST FOR THE ARCHITECT
1.
Have you visited a school with a music program such
as that desired in the school you are to plan?
2.
Have you met with the music staff to find out just what
it is they want to do in their teaching?
3.
Are you familiar with the special problems of acoustics,
lighting, sound transmission, traffic control, and
humidity control which are associated with music teaching
and public performances?
4.
Are you prepared to suggest new ways for physical
facilities to assist the music staff in reaching their
objectives?
Let us now consider various of the practical considerations
that need to go into the planning of a music room.
I will
attempt to hit on what I consider to be the high points.
1.
The question of where:
Near the auditorium is desirable
as is an outside access.
Room should be isolated from
other teaching ireai,especially if the school's design
is based on the open concept plan.
2.
The question of size and shape:
Instrumental music
rooms should be large enough to accommodate the largest
band or orchestra using the facilities.
The size of
these groups varies across the province, but sixty to
eighty is a reasonable estimate.
Some schools have
instrumental groups of one hundred or more performers
and this should not be considered impractical.
For
instrumental music rooms, 24 square feet of floor space
per pupil is recommended, for vocal rooms 18 square
feet.
An example of one school system's approach to
space requirements is a minimum of 1200 square feet
for a vocal room and 1800 square feet for an instrumental
room as used by the Toronto Board of Education.
49
Ceiling height is most important in terms of the room's
acoustics.
Regular classrooms with low ceilings parallel
to the floor are acoustically poor for large group
music making.
Height may differ at various points of
a music room since the ceiling may be sloped or scallop-
shaped or contoured in a variety of ways.
Also, the
floor may have different levels of risers. For these
reasons, the best guide is average height and this
should be between fourteen and eighteen feet for an
instrumental room and between twelve and sixteen feet
for a vocal room.
Incidentally, combined vocal-instrumental rooms are not
recommended.
3.
The question of additonal space requirements:
practice
rooms are essential in modern music facilities and
the concept of practice rooms needs to be very broad,
embracing as well as rooms in which individuals practice,
rooms thatcan be used for individual instruction,
small group instruction and small group rehearsal.
Where programs of independent study are followed, it
becomes increasingiy important to provide special
facilities for music listening.
A music office and, for instrumental music, a repair
room are worthy of serious consideration.
4The question of what goes into the music room:
risers
are definitely recommended for vocal rooms but opinions
differ as to their use in instrumental rooms.
Proponents
cite pupil-teacher eye contact, less obstructed sound
and overall control as advantages while opponents claim
a lack of flexibility in seating arrangements and that
brass and percussion tend to overpower other instruments
when there are risers.
If risers are used in instrumental
rooms two features, in my view are essential:
first
that the width of the risers vary as to the instruments
which will be played on them, second, that they be
insulated in such a way that they do not amplify the
sound of the instrument being played on them (e.g. bass
drum, bass viol).
I and my Music Consultant colleagues
with the Department of Education strongly recommend
that instruments be kept in open shelving around the
perimeter of the music room rather than in a separate
instrument storage room.
Traffic problems are alleviated
and repair bills are reduced if this is done.
50
Music rooms should also include the following:
- a chalkboard, at least one panel of which should have
staff lines for musical notation
- a large bulletin board
- shelves for students' books so located as to avoid
traffic jams
- storage racks for music folders
- in instrumental rooms, non-folding music stands with
a heavy base
- music console with stereo tape recorder and stereo record
player
- microphones for taping.
5.
The question of temperature and humidity:
Temperature
of 65-74 degrees Fahrenheit and a moisture level of
40-50% is recommended for most confortable performance,
instrumental and vocal, and in the case of musical
instruments in a room, to avoid drying and cracking.
6.
The question of acoustics:
the main factors affecting
the acoustics of a music room are those of size and
shape as mentioned earlier.
Some other considerations
are as follows:
1.
For noise control, doors should be heavy and solid
with edges well sealed, and an independent duct
system is advisable.
Windowless rooms are considered
best but if windows are used, two thinpanes are
preferable to a single thick pane.
2.
Sound diffusers on otherwise flat surface areas
of walls and ceiling help to balance sound in a
music room.
3.
Corners should be rounded off. e.g. corners of
practice rooms, music office.
4.
In order to avoid flutter echo one pair of opposite
walls should not be parallel.
This applies also
to practice rooms.
THE ACOUSTICAL ENVIRONMENT IN A SCHOOL by Professor V.L. Henderson
ABSTRACT
"Every room is an acoustical problem" - some more than
others.
Among the some are auditoria, music rooms, special
classrooms.
In auditoria the listener should not be disturbed by
undesired sound - noise, nor should occupants of other
rooms be disturbed by noise eminating from the auditorium.
The program sound should be evenly distributed to the
audience.
The decay of sound (reverberation) should be
controlled both when the auditorium is empty and when the
audience is present.
Music rooms are extension- or replacements for the stage
of the auditorium, and should acoustically duplicate it
as closely as possible.
This is beyond the powers of
the acoustical designer if he is presented with blackboards,
tackboards, storage racks covering every space where he
might locate acoustical control material.
Special classrooms include those where hearing conditions
are most critical, and those where noise is a product of
the program.
Each of these can be benefited by care in
the acoustical design.
In o. ler that the acoustical problem presented by these
rooms can be solved most effectively and efficiently, the
acoustical design must bear equal weight with that of
aesthetics, maintenance, housekeeping, and must be given
full consideration from the first instant that planning
is commenced.
THE MEDIA CENTRE by Mr. N.A. Best
1.
Flexible Patterns and Organizations for Learning
a - Traditional
iteacher with approximately thirty pupils in class
ii
pupils grouped into usually three groups according
to abilities and interests
iii
individual pupil work as member of small
group or of whole class
b - Current
ilarge groups for common instruction of approximately
100 pupils
ii
seminars of approximately 15 pupils for discussion
and group investigation
iii individual pupil work
c - Significant emphasis on individual learning
imotivation for learning necessary
ii
many activities and investigations simultanewsly
2.
Individual Instruction or Individual Learning (?)
a - Each pupil with purpose for learning
inot only a general purpose but a specific interest
or need for knowledge
ii
motivation from self, from teachers, from peers
in group
b - Each pupil with skills of individual learning
ilanguage skills
ii
research skills (even in primary grades)
c - Availability of Learning materials
iin the classroom
ii
in the media centre
51
3.
The Media Centre - a data research and distribution area
THE LEARNING MATERIAL CENTRE by Mr.B. Quan
a - Many names - library, resource centre, learning
materials centre, otc.
bMajor area
available to students, teachers, and paraprofessional
help
ii
media of all types available for research and
distribution
- books, pictures, pamphlets, periodicals,
filnstrips, tapes, records, 8mm. film loops, etc.
iii
physical facilities to display and distribute
all media for use in the centre or outside
- furniture, carrels, electrical connections,
computer connections, etc.
iv
flexibility of arrangement
vample size
vi
centrally located in school building
vii
a pleasant place to be
will
suitable for seminars or group meeting
c - Minor area - a production and maintenance area
a workroom for teachers, technicians and
sometimes students
ii
smaller than basic research and distribution
area, but with easy access to main area
iii
basic functions - preparation and maintenance
of teaching and learning materials - e.g. -
- preparation of transparencies for overhead
projector
- photocopying of documents, etc.,
- copy-stand photograpny -
- making of charts, graphs, map enlargements, etc.,
- basic cataloguing, (when not done in central
library)
- picture mounting
- receiving and distributing of 16mm films
from central film library
- simple repairs to books and equipment
- tape duplication
- local distribution of ETV via VTR and closed-
circuit TV
- storage of basic equipment
52
SPEAKER'S TOPIC:
"Physically Providing for Contemporary Media Facilities"
(Hardware & Software)
SCOPE & R' 3UME:
1.
History & Trends - Media, Materials, Equipment and Space:
a)
Old and Contemporary
b)
Utilization
2.
Physical Requirements:
a)
Service Facilities
b)
Environmental Needs
3.
Construction Requirements:
a)
For Installation Now
b)
For the Future
4.
Cost of Facilities:
a)
Immediate
b)
Provisional
RESUME
and Trends -- Media, Materials, Equipment and Space:
Old --- (Essentially Visual)
b)
Utilization --
0Purpose --
-- Storage
1.
History
a)
-- Books and other Printed Matter (Library)
-- Maintenance and Repairs
-- Slides and Film
-- General Use
Contemporary --- (Audio-Visual) and (Special)
-- Reproduction
Audio
Visual
Special
ii)
By Whom
Radio
Books
Photocopying
Receivers
-- Teacher/Custodian
Magazines &
Microfilming
Discs &
1 way
Players
Perion;cals, etc.
-- Individual Student
Tapes
2 way
Recorders
Pictures, Charts
Computer
-- Special Groups
(Language Machines
and Lab.)
& Documents
Facilities
(Time Sharing,
Slides, Trans-etc.)
parencies, Film
-- Class or Classes
Strips, etc.
2.
Physical Requirements:
Viewers/Projectors
a)
Service Facilities -- (flexibility paramount)
1)
Furniture
F11145
GE4
ETV
CLOSED
CIRCUIT
Video-
Tape
Shelving, Tables, Carrels, etc.
2)
Electrical
Outlets & Raceway Systems
(including underfloor)
3)
Special
Water, etc.
b)
Environmental Needs --
i)
Space -- Areas and Rooms
- - Library Space
- - Special Materials Centre
53
b)
Environmental Needs (Cont'd)
- - Work or Production Space
- - Storage Space
- - Assembly Space
ii)
Zoning -- Partitioning
- - Location
- - Privacy and Isolation
iii)
Climatic -- Comfort
- - Heating
-- Ventilation
- - Air Conditioning
iv)
Audio - Acoustical
- - Ceiling Tiles & Wall Pane'..s
- - Carpets & Drapes
v)
Visual - Lighting
- - Natural
Artificial
- - Book Shelves & Catalogue Files
- - Reading Tables
- - Carrels
54
3.
Construction Requirements:
a)
For Installation Now --
-- Readily incorporated as an integral part
of the building.
Primarily a space and
electrical problem.
- - Flexibility must be considered.
b)
For the Future --
-- If equipment is not being purchased now,
it is important to make some provisions
for the future, to minimize major alter-
ations.
It may be difficult to make
satisfactory provisions.
- - Services may be installed as Stage 1
before equipment is purchased at a
later date as Stage 2.
e.g. TV system
4.
Cost of Facilities:
a)
Immediate -- -- Costs are minimized when services are
incorporated at the time of construction.
- - Additional expense is necessary to obtain
maximum flexibility.
b)
Provisional --
-- Provisional requirements may be adapted
to fit a particular budget, although
results may not be entirely satisfactory.
RESUME
1.
History and Trends -- Media, Materials, Equipment and Space:
a)
Old --- (Essentially Visual)
- - Books and other Printed Matter (Library)
- - Slides and Film
Contemporary --- (Audio-Visual) and (Special)
b)
Utilization --
i)
Purpose --
-- Storage
- - Maintenance and Repairs
- - General Use
- - Reproduction
Audio
Visual
aecial
ii)
By Whom
Radio
Books
Photocopying
Receivers
-- Teacher/Custodian
Magazines &
Microfilming
Discs &
1 way
Players
Periodicals, etc.
-- Individual Student
Tapes
2 way
Recorders
Pictures, Charts
Computer
-- Special Groups
(Language Machines
and Lab.)
& Documents
Slides, Trans-
parencies, Film
Facilities
(Time Sharing,
etc.)
-- Class cr Classes
Strips, etc.
2.
Physical Requirements:
Viewers/Projectors
a)
Service Facilities -- (flexibility paramount)
1)
Furniture
FILMS
GE17
ETV
CLO ED
CIRCUIT
Video-
Tape
Shelving, Tables, Carrels, etc.
2)
Electrical
Outlets & Raceway Systems
(including underfloor)
3)
Special
Water, etc.
b)
Environmental Needs --
i)
Space -- Areas and Rooms
- - Library Space
- - Special Materials Centre
53
CONSTRUCTION SYSTEMS FOR SCHOOL BUILDINGS by Mr. J.C. Rankin
A SYSTEM - What is it?
Everyone has his own definition or at least his own
understanding of this phrase.
It would appear that it is
not only fashionable but essential to have a special language
these days.
In order to clarify this discussion it might
be well if we could agree on a deZinition which it is
proposed might be:
A system is a working totality formed of often diverse but
integrated Parts, subject to a common plan or serving a common
purpose.
A system can be very complex or it can be very
simple, it can be a guided missile and its control centre -
a child's play with a skipping rope.
I believe that we must
go further and consider other sub-divisions and suggest
that when we are talking about a building system we are
talking of hardware and when we are talking about the systems
approach we are talking about a management approach a
technique or discipline.
The systems approach is in reality a thorough following
of five steps.
System definition
System analysis
System design
System implementation
Final evaluation
khen this is applied to the built environment the systems
approach means effecting a constant integrated and reasoned
pursuit of a program from the instant a need is conceived
until it is physically satisfied and the satisfaction
documented.
If that sounds like a rationale for deliberately
planned sex - it depends on whether you use the systems approach.
Having defined the systems approach we should perhaps look
at the results of different interpretations and uses of
the method.
Today we can examine briefly two different
programs and we have the unusual opportunity here of
viewing the child before the parent.
The SEF program to
which we are now addressing ourself is in some very real
ways a stepchild of the CLASP program.
Very briefly the
history of the SEF program may be stated as follows:
In 1963 the Honourable William Davis, Minister of Education
for the Province of Ontario called together a conference
on School Planning and Design.
Held in Toronto it was
attended by some 1600 people representing every discipline
both inside and outside the education system who are
concerned with the problems.
As a result of this conference
it was decided that a major effort must be made to
investigate the requirements of education for the future
and of methods to satisfy the need.
It was further decided
that the urban conglomerate which is Metropolitan Toronto
provided an ideal location for this kind of study because
within its boundaries it offered examples of nearly all
the problems facing education from scattered sporadic
development of previously rural property to the highly
concentrated urban redevelopment.
There were many more
people available within short range for consultation than
in any other location in the Province of Ontario.
Two
things happened-a Minister's Advisory Committee on School
Design was instituted headed by Dr. K.F. Prueter and a
Division of School Planning and Building Research was set
up within the Department of Education headed by Mr. F. Nicol.
These two groups drew to the attention of the Metropolitan
Toronto School Board the experiment in education facilities
that was then taking place in Southern California known as
SCSD and established to the Boards satisfaction that this
was a major effort which represented a significant change
in the approach to school facility provision.
The Metropolitan
Toronto School Board set up an Advisory Committee representing
the City and Borough Boards of Education the National
Research Council and the Design Professions in the words
of the minutes of the meeting of November 5, 1965 to under-
take a Major Study of School Building Practices in Metropolitan
Toronto with particular reference to -
(a)
development of systems and components
specifically for school use
(b)
more effective application of principles
of modular construction in achievement
of greater fl.ixibility of interior design. 55
The Advisory Committee approached Educational Facilities
Laboratories in New York who had underwritten the research
costs in the SCSD project e_nd requested their assistance
in the Metropolitan Toronto Research Project.
SEF happily
has had the full support of Educational Facilities Laboratories -
its staff and their advisory capabilities as well as a very
significant financial contribution.
EFL has underwritten
1/3 of the total costs of the SEP project.
The Advisory
Committee then set up a staff to under cake the project
and appointed Mr. Hugh Vallery as Academic Director and
Mr. R.G. Robbie as Technical
Director.
There is a joint
Research Director, Dr. John Murray.
The academic research
staff consists of four senior and four junior researchers,
the technical staff two senior and two junior researchers
plus a secretariate.
The premise on which SEF has functioned
is that the need must be defined as accurately as possible
and the requirements stated in terms of required performance.
The physical facilities which we now expect to form the
parts of the First SEE Building System have been a magnificent
response by the construction industry to a detailed performance
specification.
I must point out that no research done by
SEF was basic, fundamental research.
SEF concerned itself
with researching into precedent, reading the literature that
was available produced anywhere in the world, visiting
many schools in all parts of North America and presenting
this material to a series of academic and technical
committees for their comments and assistance.
To
date same two hundred and fifty teachers, principals,
superintendents, coordinators and directors have cooperated
in the academic side of the program and on the technical
performance specification preparation some one hundred
practicing professionals, plus representatives of over
four hundred manufacturers, contracting and sub-contracting
organizations and the building trades unions have all made
significant contributions.
The final results which SEF
received in the form of tenders on the 7th January 1969
represented the efforts of thirty-six companies.
It has
been estimated that the construction industry invested some
3.6 million dollars in responding to the SEF specifications.
How was this done? Why? The answer is very simply that
school construction in Metropolitan Toronto is big business.
The average budget for capital works in Metropolitan Toronto
area has exceeded seventy million dollars a year for the
last several years and that amount in every case represents
a significant cutback from the original statement of requirement
which would run anywhere from one hundred and one to one hundred
and sixty-seven million dollars and these ladies and gentlemen
56
are annual requirements for capital expenditure.
It hae been estimated conservatively that the capital budget
.)r the next ten years in Metropolitan Toronto would have
to exceed five hundred million dollars.
Following the
SCSD example in Southern California the Metropolitan Toronto
School Board assembled a package of school buildings.
The
City of Toronto and the Borough School Boards nominated into
the SEF program thirty-two buildings and the Metropolitan
Toronto School Board offered to the construction industry
a contract for not less than one million square feet and
not more than two million square feet of school construction
for completion in the calendar years of 1970 and 1971.
With this as the initial contract and the ongoing school
program as a very real home-grown market the construction
industry responded magnificently.
To what did they respond?
SEF arbitrarily divided education buildings into eleven
parts.
These were structure,atmosphere, lighting-ceiling,
interior space division, vertical skin, plumbing, electric-
electronic, caseworks and furniture, roofing, interior
finishing and a host of uncoordinated items which were
called non-system.
The first ten categories were called
sub-systems.
These were carefully studied and with the
assistance as mentioned earlier of specific technical
consultants and generous participation of the whole construction
industry, a set of performance specifications was produced.
Tenders were invited from prequalified sub-system contractors
on the 9th July last year.
The results have been beyond
the wildest dreams of most of those dealing with physical
school facilities.
It is estimated that the requirement
as stated in the specifications which represents a substantial
increase in the quality of school facilities if applied to
or responded to in the traditional design method in the
Metropolitan Toronto area would require an increase in
budget of 25% to 30%.
Items such as all year round air
conditioning, carpeting in over 60% of the area, clear
spans up to 65 feet for floors and greater than that for
roof construction.
The response has been such that it
appears that schools can be constructed using the First SEE
Building System for a minimum saving of 5% of the current
ceiling cost formula of Metropolitan Toronto with intelligent
planning up to 18% saving might be achieved.
One point
that must be made abundantly clear is that the First SEF
Building System is not a standard plan, it is nota standard
building:
it is a very sophisticated kit of
parts that can
be put together by the design professionals in
an almost
infinite variety of ways.
Because of the fact that the
system can be assembled so many ways obviously some of these
are less efficient than others and for this reason it is
impossible to say that the cost will be any particular
number any more than it is possible to be definite
using
traeitional methods and materials right now.
One of the
conditions that SEF considered to be most
important in its
tendering requirements was the requirement of interfacing
by the Sub-System Tenderers.
This was a requirement in
the specifications that Sub-System Tenderers whose
materials
abutted one another must jointly decide on the
exact line
of division between sub-systems and establish
to their
mutual satisfaction who does what and in addition
it was
a requiremant of SEF that the tenderers do this with at
least two tenderers in
every one of the mandatory interface
categories.
As a result when the tenders were evaluated
it was necessary to enlist the assistance of
a computer.
Potentially there were well over one million possible
combinations.
Bearing in mind that a lack of time prevented
some people from interfacing with everybody in a
thorough
manner the number was reduced.
However, the number of
viable combinations in other words, the number
of complete
building systems that was offered to the Metropolitan
Toronto
School Board was in excess of 13,000
everyone of which
met the performance specifications of SEF,
The hardware
that has been presented to SEF represents
a very careful
analysis of the construction problem and the solutions
generally speaking represent an organizational
breakthrough
rather than a technical breakthrough.
The structure is a steel joist and truss
combination using
a constant depth throughout the
span range and a constant
finished column dimension over the
fireproofing.
The roof
deck is a traditional metal roof deck and
the floor,a metal
pan with a concrete swab topping.
Wind bracing is achieved
by x-bracing in fact a thoroughly traditional solution.
The Atmosphere sub-system consists of a series of individual
electrically fired or operated units designedprimarily for
roof top mounting but with the capability of
being installed
in spaces adjacent to the exterior of
a building.
The
units have a 10,000 CFM capacity approximately and deal
with a variable percentage of fresh air.
Each unit is
entirely self-contained and includes heat
generation,
refrigeration, humidification, filtration and controls the
space temperature to within + or -2° of a 6° spread on a
year round basis in spaces of 400 square feet or more.
The Lighting-Ceiling Sub-System is based
on the five foot
by five foot planning grid which SEF adopted.
It provides
lighting, acoustic attenuation and absorbtion at two
levels,
six different categories of lighting,
as well as incandescent
lighting for specific purposes such as exits,
displays, etc.
General illumination is being provided tothe learning spaces
using only 2 watts per square foot in place of the
average
traditional four watts
per square foot.
This lighting is
controlled in two levels so as to allow note
taking during
audio-visual presentations.
The lighting-ceiling sub-system
provides the fire membrane for the structural sandwich
the floor-ceiling sandwich as well
as providing the diffuser
the boot and the fire damper for the
atmosphere sub-system.
The Interior Space Division offers three basic
types of
interior walls.
Those that are relocatable such as
are
found in many office buildings
today.
Those that are
operable are the accordion type or panel
type movable walls
and also fixed walls which have
a fire rating.
The vertical
skin a precast concrete one has
a series of panels from
which the designer selects.
The system is erected by first
attaching the spandrel panels to the columns and the
infill
panels then span from floor to ceiling.
It may interest
you to know that the size of the glazed opening that is
being offered is based on the air conditioningscapabilities
ratner than on any other basis.
The Plumbing Sub-System is a
rationalizing of the use of
equipment and a considerable amount of
prefabrication of
the plumbing tree for the SEF
project.
You can have any
basin you wish as long as it is white and
is the one offered.
By limiting the selection to one of each
type of plumbing
fixture there has been substantial
gain to the purchaser.
The Electric-Electronic
Sub-System is perhaps the most
57
exciting of those developed in response to the requirements
of the SEF program.
It includes power and communication
wiring within the occupied space.
Primary electrical service
transformers and the main switchboard are non-system
but beyond this the electrics are all under one contract.
Distribution points are set up at approximately sixty foot
centres in both directions throughout the building and every-
thing from there out will be done by plug-in pieces.
Certain testing remains to be done but we have been very
fortunate to have excellent assistance and cooperation of
the Ontario Hydro.
The communication system includes the
normal public address and paging systems program and clock
Systems room to room inter-communication local sound
reinforcement and even fire alarm signalling.
The Casework Sub-System was not tendered at the same time
and the specification for this sub-system is currently
being reviewed and commented on by the building industry.
It is planned that this will be tendered soon with the
closing during the summer months and after testing an official
contract may be awarded in the early fall.
The Roofing Sub-System is a rationalizing of the current
roofing practices and does not offer anything radically
new except a very tidy flashing detail, roof to wall all
I might add, at a very attractive price.
The carpet which we have been offered is a polypropelyne
material that was developed specifically for the SEF program.
It is accompanied by a six year guarantee for both material
and installation.
The Gymnasium Flooring material that will be used in the
SEF system is a resillient material which we believe to
have any properties superior co that traditionally used
and the educators are particularly enthusiastic.
A test structure is being erected as an addition to Eastview
Public School in Scarborough, Ontario and this addition
should hopefully be completed in the early part of July
of this year.
During the month of July it is intended to
carry out extensive testing of the addition to ensure the
compliance of the system with all SEF specifications and
the SEP Technical Staff has every reason to believe at this
date that there will be no serious difficulty.
We would be remiss if we considered the building system
58
successful as it appears to be. To be a final answer SEF
believes that this is the first step in the evolution of
the provision of physical facilities for education and indeed
for all of society's needs.
Evaluation of the results
should point the way to newer concepts of what is reasonable
and possible for the next step.
Perhaps the most significant
experience that those of us at SEF have had in the past two
and half years is the integration of the user in the
facilities process.
The clearly stated definition of
requirements has been fundamental; and the participation of
all parties in the system analysis, system design and the
implementation has led us to the point where we believe
that final evaluation will point out an irreversible pathway
for the future.
CONSTRUCTION SYSTEMS FOR SCHOOLS by Mr. S.J. Solomon
"C.L.A.S.P."
A building system has been defined as a method of building
that justifies a brochure.
There is a lot of truth in
that but perhaps it would be fair to define it as a method
of building that has been allied to some form of organization
for its economic exploitation.
A bit dry, perhaps, but
you will note that this gives as much emphasis to the
organization backing it as to the method itself and I think
rightly.
The importance of the organization in system
buildirg has been particularly evident in the U.K. over
the la, .t ten or so years where so many good ideas have
been floundering around looking for a sponsor.
These start
in the heads of architect or engineers but never materalise
because the designers cannot persuade either client or
building of their potential.
The client wants to deal
with an organization with sound financial backing and the
guarantee of service to go with it, and the builder wants
some sort of guarantee that there is a market for it.
Because of the fragmented nature of client, professional
and builder's organizations, the three rarely come together.
It will be useful to spend a little time categorizing
systems from the viewpoint of the sponsor's organizations.
One can identify three main groups.
Firstly, there are
the systems sponsored by manufacturers of building products
or components.
Their motive for launching a system is
usually to create an extension to their normal market.
Such systems tend to suffer from their lack of site
expertise.
While the production and design quality of the
components
is usually good, the process of putting them together
on
site is often not worked out to achieve maximum efficiency.
An exception to this, which you are doubtless familiar
with,
are the systems for moveable classroom units where the amount
of work on site is cut to an absolute minimum.
Another disadvantage of the manufacturer's system is that
it usually means some special tooling and the manufacturer
finds it difficult to amortise his tooling costs, in
particular during the 'stop' part of the familiar 'stop-go'
cycle in building activity.
During the 'go' part of the
cycle there is full employment in the building industry
and systems score by the fact that they use labour more
productively.
It is during periods of under-employment
that systems suffer and manufacturers are tempted to
cut their losses and quietly buy their promising new creation.
The system sponsors in the second category are rather
more
resilient.
These are the builders.
In the field of
housing, it is usually the builders who launch new systems,
the systems usually being either a rationalization of the
building methods they have been using for many
years or,
as has often happened in the U.K., a high rise concrete
system licensed from the Continent.
These systems tend
to be more resilient because they are often treated
as a
side-line to the builder's main activities and little is
lost in times of low demand as the builder
can leave his
system in cold storage while he concentrates on traditional
building.
Builder-sponsored systems are naturally good
on site
productivity, using efficient techniques backed
up by
sound site organization.
They are usually leas good on
efficiency of component design related to factory
production.
Sometimes the builder will manufacture his
own components
and this is particularly common in low-rise housing
systems,
but the components are usually designed with thebuilder's
own workshop facilities and craft labour in mind and they
are thus largely traditional in concept.
Very occasionally builder and manufacturer act
as co-sponsors
of a system, resulting in factory productionexpertise
geared to an efficient site organization.
However, there
is one factor that this set-up still lacks
and that is a
clear lead on user requirements.
A system sponsor runs
the risk that, by broadening the appeal of his
system to
try to cater for as many clients as possible, he succeeds
in satisfying none of them.
My third category of sponsor, the client, has
no difficulties
on this score.
The system development team set up by the
client usually undertakes an appraisal of
client needs and
user requirements before embarking on the design of
the
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bits needed to meet them.
The S.E.F. Project in Toronto
is an example of a client sponsored system with the
difference that the technical team have stopped short of
actual component development and have concentrated on
defining user requirements and setting-up the framework
to enable the building industry to design the parts.
I
would like now to describe one of the best known of client
sponsored systems, namely CLASP.
This was one of the first client sponsored systems and
certainly the first to bring together several clients
into a Consortium in order to build up a viable building
programme.
The system was designed initially to solve
the problems of school building in the County of Nottinghamshire,
development work commencing in 1955.
The problems were acute.
There was a severe shortage of
skilled labour, traditional sc' 'ols were taking too long
to build and, being one-off solutions, were not amenable
to cost control.
Another problem was that subsidence
due to coal mining was necessitating special foundations
that was forcing the Ministry of Education to allow such
schools up to 10% additional grant.
After a period of user study, the initial system development
was completed in six months and the prototype school
opened six months later.
Building time was halved, a
framework for future cost control was set up, and the 10%
additional grant for a subsidence site was handed back
to the Ministry.
Mining subsidence is incidental to
the system and I refer to it merely as an example of how
the analysis of client needs and development of a standard
building method gives the opportunity to question certain
assumptions about schools and building generally that can
lead to significant savings in cost.
It was evident that Nottinghamshire's41 million annual
building program was not large enough to attract significantly
lower prices from component suppliers, so other countries
with similar problems were encouraged to join in.
Thus
was created the Consortium of Local Authorities Special
Programme.
The combined annual total of building value
rose froraLl million in 1957-58 to aboutit20 million in
1967-68.
Somewhere in between is the optimum size of program
-
where the maximum benefit of price reduction due to bulk
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buying is achieved without exceeding the capacity of
medium sized suppliers and thus reducing the numbers tendering.
The system consists of a pin-jointed steel frame, sitting
on a concrete raft, to which are fixed timber upper floors
and roof and various forms of cladding and windows.
Apart
from the fundamental re-appraisal of design for mining
subsidence there was no attempt to do anything revolutionary.
Design of details was based on function and the temptation
to make emphatic statements was avoided.
The success of
these schools was due to the general excellence of environment
they created.
A poor architect using the system might
produce a mediocre school but it would
effort to produce a really bad one.
Athe wilder fancies of an architect but
are sensitively designed it will prove
to good sclool design.
take tremendous
system will inhibit
provided the parts
an excellent means
Interior views of typical CLASP schools demonstrate the
high quality of finishes obtained.
It is very easy to
clothe the bare bones of a system with expensive finishes
but here it has been achieved within normal cost limits
by a striving on the part of the development architects
to put the money where it can be seen.
This bonus is
possible in the client based system as the architect has
full control of the design of the parts.
The hidden
elements such as the frame, foundations, floor and roof
are stripped to their bare essentials leaving a bigger
proportion of the cost of building free for such things
as hardwood doors and frames instead of softwood and
foam-backed vinyl floors instead of thermoplastic.
The biggest single project built in CLASP is York University,
by Architects Robert Matthew, Johnson- Marshall and Partners.
All of the 110 million scheme except the library and
auditorium is in CLASP.
The main reasons for the choice
of CLASP were speed of erection and the fact that there
was not sufficient building labour to cope with the university
in traditional construction on top of all the other proposed
building in the region.
The 100th CLASP project in Great Britain is at present being
built.
In the twelve years of its existence, the system
has undergone constant re-appraisal and development with
Mark 5, incorporating the change to metric, due
in 1972.
In the 1961 Triennale Exhibition in Milan the British
Pavilion, a typical primary school built in CLASP, won
the Gran Premio Award.
The Italians took some convincing
that the quality of the building was typical cf schools
in Britain, but they were very enthusiastic and tried to
persuade the British Ministry of Education to make the
system available in Italy.
Such a venture was outside the
scope of a Government body, and the Consortium was too
loosely knit a body to undertake such work.
So the firm
that was principally involved with the system, namely
Brockhouee. Steel Structures Ltd., was asked if it wished
to launch the system abroad.
The Brockhouse engineers
had collaborated with the Consortium right from the earliest
stages and the firm was then, and has been since, the sole
supplier of the steel frame.
About the same time as the
Triennale Exhibition, CLASP was being considered for use
in Germany for schools for the British Army of the Rhine.
The Brockhouse Group set up companies in both countries
and the system was adapted to suit local conditions.
This
meant taking into consideration such aspects as climate,
building regulations, user requirements, available materials,
level of quality, balance of building trades and so on.
The Brockhouse company in each case performs roughly
the same function as the Consortium does in Britain,
developing the system, organizing the program, entering
into agreement with local manufacturers for the supply of
components and giving advice to architects and builders
on how to use it.
The technical development is done locally
and is co-ordinated in all countries outside the U.K. by
the International Division of Brockhouse Steel Structures Ltd.
This set-up really amounts to a fourth category of sponsor
where a commercial firm takes over a system from the original
client sponsor and provides the necessary organization to
link client and architect with manufacturers and builders.
The Germans have produced a very refined version of the
system which reflects the high quality that they demand of
their buildings.
The Italians, on the other hand, spend
much less per puil.
When introducing the system into
a new country, the design concept must be flexible enough
to allow the parts to assume their correct level of quality.
About eighty-seven buildings have been completed in Germany
and a similar number in Italy.
The system is also established
in France and Switzerland and, since last year, in
South
Africa.
An interesting project in France was the group of buildings
in Grenoble built at great speed to be ready for the start
of the last Winter Olympic Games.
The buildings served
as administration centre during the Games, and afterwards
were handed over to the community as a secondary school.
The CLASP system has as many forms as the countries in
which it exists.
The form it will finally take in Canada
has not crystallized yet, nor is it possible at present
to forecast when it will be ready for use.
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